Mutant enzymes

ABSTRACT

This invention relates to mutant enzymes with enhanced properties and processes for oxidation of organic compound substrates using such enzymes.

FIELD OF THE INVENTION

The invention relates to mutant enzymes with enhanced properties.

BACKGROUND OF THE INVENTION

Biological enzyme catalysts, such as P450_(BM-3) enzymes, find increasing use in a variety of industrial applications, ranging from synthesis of fine chemicals, intermediates, pharmaceuticals and drug metabolites to degradation of organic chemical contaminants and pollutants. Protein engineering, using directed evolution or site-directed mutagenesis, can be used to isolate variants of known enzymes, which may create new opportunities and applications for their catalytic activities.

P450_(BM-3) from Bacillus megaterium (1) belongs to the superfamily of cytochrome P450 enzymes. There are over 7,700 genes encoding P450 enzymes in the various gene sequence databases. Nomenclature of P450 enzymes has been systemized. The superfamily of enzymes are referred to as CYP, followed by a number for a family of enzymes (hence CYP1, CYP51, CYP102, etc.) which are divided into subfamilies denoted by alphabets (hence CYP1A, CYP101B, etc.) and each sub-family member is denoted by a number (hence CYP1A1, CYP3A4, CYP101D3, etc.). A gene encoding a CYP enzyme is denoted by italics, e.g. CYP101A1 gene. P450_(BM-3) has been designated CYP102A1, i.e. it is the first member of the CYP102 family. Henceforth the systemic name of CYP102A1 will be used for P450_(BM-3).

CYP102A1 (1) is an attractive enzyme for biotransformation applications because it is catalytically self-sufficient. Unlike other P450 enzymes, in which the P450 monooxygenase and the electron transfer co-factor proteins are separate entities, CYP102A1 has the haem monooxygenase domain fused to the diflavin electron transfer reductase domain, which contains both the FAD and FMN prosthetic groups in a single polypeptide. The natural substrates of CYP102A1 are believed to be linear or branched medium chain fatty acids (1,2). The crystal structure of the CYP102A1 haem domain became available in 1993 (3), revealing the active site structure and the presence of a substrate access channel. The crystal structure with a bound substrate, published four years later, indicated a change in the side chain conformation for F87 upon substrate binding (4).

Protein engineering of CYP102A1 has been reviewed (5-7). Early studies focused on the active site residue F87, with the F87V, F87A, F87Y and F87G mutations showing varied effects on the activity and selectivity of fatty acid oxidation (8-11). Mutations at F87 have been found to be beneficial to the oxidation of a variety of substrates (7). Residues such as F42, R47, and Y51 at the entrance to the substrate access channel were also targeted. Neutralizing or reversing the charge at the 47 position altered the substrate specificity (8,12), as did the hydrophobic substitution Y51A, while the F42A mutation lowered enzymatic activity (10). WO0031273 disclosed the use of the R47L/Y51F couplet of mutations to promote entry, binding and oxidation of hydrophobic organic molecules such as polyaromatic and terpenoid hydrocarbons. The couplet was also combined with the F87A, I263A, A264G and M354A mutations to give enhanced activity and/or product selectivity of substrate oxidation (13,14). The R47L/Y51F combination, and the R47L and Y51F mutations on their own, are now commonly used in CYP102A1 engineering (15-19).

In addition to rational selection of mutation sites, screening techniques have been utilized to identify other mutations and mutation sites which have desirable effects on activity and selectivity. Random or site saturation mutagenesis was applied to CYP102A1 as early as 1997 (20). NO20020380 disclosed the use of indigo formation via indole oxidation as a screening method to discover CYP102A1 mutants with new activity. Saturation mutagenesis was applied to a number of residues likely to affect substrate binding, and the mutant A74G/F87V/L188Q was reported to oxidize a wide range of organic molecules with enhanced activity and altered selectivity compared to the wild type (21-25). AT342351T disclosed the formation of p-nitrophenol, which is spectroscopically detected, via oxidation of a ω-p-nitrophenoxy-carboxylic acid, as a screening procedure in a set of random mutagenesis experiments. The mutations V26T, R47F, S72G, A74G, F87A&V, L188A,G,N,K,Q,R,S&W, M354T were disclosed (26,27).

The p-nitrophenol screening method was extended by using p-nitrophenoxyoctane as the surrogate substrate. WO2002083868, EP1470219 and US2005202419 (subsequently corrected in WO2005017116, EP1660646, and US2005037411) disclosed the mutations L52I, I58V, F87A, H100R, S106R, F107L, A135S, M145A&V, A184V, N239H, S274T, L324I, V340M, I366V, K434E, E442K, V446I.

WO2003008563 and US2003100744 disclosed the results of further rounds of random mutagenesis, gene shuffling and screening using the same method, and reported the mutations M30I, E64A, V78A, F87A,D,G,H,I,K,N,R,V&W, H138Y, F162S, H171Q, T175I, V178I, A184V, N186D, D217V, I220T, K224I, S226I, D232G, T235A, H236Q, E252G, R255S, I258T, I259V, T268Q, A290V, A295T, L353V, D370Q, E380G, G396M, T411A, M416L.

WO2005017105, US2005059128, and EP1639091 disclosed the use of the same methods and reported the mutations R47C, L75I&W, V78A,F&T, A82L,F,G,I,S&T, F87I,L&V, T88C, K94I, P142S, T175I, A184V, F205C, S226R, H236Q, E252G, R255S, T260,L,N&S, A290V, A328V&M, L353V.

WO2006105082 then disclosed the mutations R47C, V78F, A82S, K94I, P141S, T175I, A184V, F205C, S226R, H236Q, E252G, R255S, A290V, A291V, A328F, L353V.

These series of mutants generated by random mutagenesis show enhanced activity for the oxidation of alkanes from ethane to medium chain alkanes (28-30). There were also selectivity changes, in particular when the directed evolution variants were combined with mutations introduced into the active site by site-directed mutagenesis, e.g. in octane oxidation where the mutations shift the site of oxidation towards the terminal carbon (31), selective epoxidation of terminal alkenes (32), and enantioselectivity in the oxidation of cyclopentanecarboxylic acid derivatives (33). It is notable that better results can often be obtained by combining directed evolution with rational re-design.

CYP102A3 is a P450 enzyme in the same sub-family as CYP102A1. Random mutagenesis of CYP102A3, followed by alkane oxidation and monitoring NADH formation in the presence of an alcohol dehydrogenase specific for terminal alcohols, gave rise to a mutant that formed 50% 1-octanol from octane oxidation. This is the highest proportion of terminal C—H bond oxidation of a linear alkane observed to date by an engineered CYP102 family P450 enzyme (34).

There is a continuing need to isolate further mutants of industrially useful enzymes, such as CYP102A1 enzymes, in order to further understand the impact of structural changes on their catalytic mechanism, improve their catalytic turnover, and expand their range of substrates and/or products. In general, engineering of P450 enzymes such as CYP102A1 is carried out to enhance enzymatic activity, with control of product selectivity and substrate specificity being important secondary objectives. Mutations and mutation sites which can couple selectivity control to enhanced monooxygenase activity are conspicuously lacking, such that enzymatic turnover of compounds may be fast but not sufficiently selective, or there is some selectivity but the reactions are slow, or the desired product is not formed. There is also a need for screening methods that can provide mutants with enhanced activity and/or desirable selectivity.

SUMMARY OF THE INVENTION

It has now been found that, according to the present invention, substitution mutations at specific positions of CYP102A1 have desirable effects in enhancing monooxygenase activity and also provide for altered selectivity. These mutation sites were identified through use of an innovative screening method that provides for selection both of enhanced activity and enhanced/altered selectivity.

The present invention provides a mutant CYP102A1 enzyme, which has enhanced monooxygenase activity and/or altered selectivity and comprises a substitution at one or more of positions 117, 131, 191, 215, 276, 307, 330, 377, 401, 403, 425 of CYP102A1. There is additionally provided a process for oxidizing a substrate which is an organic compound, which process comprises oxidizing said organic compound with a mutant CYP102A1 enzyme of the invention.

The claimed substitutions form part of the same inventive concept, as they share effects in enhancing monoxygenase activity and/or alter selectivity of CYP102A1. Substitutions at positions 330, 401 and 403 also exert their effects via common structural and/or functional mechanisms, as outlined below.

Sequence in the Sequence Listing

SEQ ID NO:1 is the sequence of CYP102A1.

DESCRIPTION OF FIGURES

FIG. 1: Location of relevant residues in CYP102A1 (P450_(BM-3)). Palm denotes a fatty acid substrate of the enzyme.

FIG. 2: Comparison of key residues in the substrate access channel and active site of wild type CYP102A1 and the A330P mutant, highlighting the structural perturbations at P329 and A328 resulting from the A330P mutation.

DETAILED DESCRIPTION OF THE INVENTION

The invention is applicable to natural and artificial homologues of CYP102A1, for example, which comprise sequence that has at least 40% amino acid sequence identity to CYP102A1. Such homologues typically comprise amino acid sequence which corresponds to (i.e. is homologous to or the same as) the haem monooxygenase domain of CYP102A1 (represented by amino acid positions 1 to 480).

The enzyme of the invention comprises (or consists of) sequence which has at least 40% identity to SEQ ID NO:1 (the sequence of CYP102A1). In preferred embodiments, the sequence may be at least 55%, 65%, 80% or 90% and more preferably at least 95%, 97% or 99% homologous thereto over at least 20, preferably at least 30, for instance at least 40, 60, 100, 200, 300, 400 or more contiguous amino acids, or even over the entire sequence of the homologue. In one embodiment the enzyme of the invention has any of the specified percentage homologies when compared to amino acid residues 1 to 480 of CYP102A1. The contiguous amino acids may include the active site. This homology may alternatively be measured not over contiguous amino acids but over only the amino acids in the active site. Thus the homologue is typically at least 40% homologous to CYP102A1 on the basis of amino acid identity. The enzyme of the invention may have a percentage identity with CYP102A1 sequence which is the same as any of the specific percentage homology values (i.e. it may have at least 40%, 55%, 80% or 90% and more preferably at least 95%, 97% or 99% identity) across any of the lengths of sequence mentioned above.

The homologous sequence may represent a mutated portion of the CYP102A1 sequence and/or may be present in the form of the full-length fused polypeptide of the enzyme of the invention.

Any of the homologous proteins (i.e. described as being homologous to another protein) mentioned herein are typically at least 40% homologous to the relevant protein. Homology can be measured using known methods. For example the UWGCG Package provides the BESTFIT program which can be used to calculate homology (for example used on its default settings) (Devereux et al (1984) Nucleic Acids Research 12, 387-395). The PILEUP and BLAST algorithms can be used to calculate homology or line up sequences (typically on their default settings), for example as described in Altschul S. F. (1993) J Mol Evol 36:290-300; Altschul, S, F et al (1990) J Mol Biol 215:403-10.

Software for performing BLAST analyses is publicly available through the National Center for Biotechnology Information (http://www.ncbi.nlm.nih.gov/). This algorithm involves first identifying high scoring sequence pair (HSPs) by identifying short words of length W in the query sequence that either match or satisfy some positive-valued threshold score T when aligned with a word of the same length in a database sequence. T is referred to as the neighbourhood word score threshold (Altschul et al, supra). These initial neighbourhood word hits act as seeds for initiating searches to find HSPs containing them. The word hits are extended in both directions along each sequence for as far as the cumulative alignment score can be increased. Extensions for the word hits in each direction are halted when: the cumulative alignment score falls off by the quantity X from its maximum achieved value; the cumulative score goes to zero or below, due to the accumulation of one or more negative-scoring residue alignments; or the end of either sequence is reached. The BLAST algorithm parameters W, T and X determine the sensitivity and speed of the alignment. The BLAST program uses as defaults a word length (W) of 11, the BLOSUM62 scoring matrix (see Henikoff and Henikoff (1992) Proc. Natl. Acad. Sci. USA 89: 10915-10919) alignments (B) of 50, expectation (E) of 10, M=5, N=4, and a comparison of both strands.

The BLAST algorithm performs a statistical analysis of the similarity between two sequences; see e.g., Karlin and Altschul (1993) Proc. Natl. Acad. Sci. USA 90: 5873-5787. One measure of similarity provided by the BLAST algorithm is the smallest sum probability (P(N)), which provides an indication of the probability by which a match between two nucleotide or amino acid sequences would occur by chance. For example, a sequence is considered similar to another sequence if the smallest sum probability in comparison of the first sequence to the second sequence is less than about 1, preferably less than about 0.1, more preferably less than about 0.01, and most preferably less than about 0.001.

Typically the homologous protein differs from the relevant protein by at least, or less than, 2, 5, 10, 20, 40, 50 or 60 mutations (each of which can be substitutions, insertions or deletions) when compared to all of the protein or over any of the lengths of contiguous amino acids mentioned above.

The enzymatic activity of the CYP102A1 enzyme of the invention is typically measured in vitro using any of the substrates or conditions mentioned herein and is given as the NADPH oxidation rate, the product formation rate and coupling efficiency. The rates are turnover frequencies and given in (nmol NADPH) (nmol CYP102A1)⁻¹ (min)⁻¹ or (nmol product) (nmol CYP102A1)⁻¹ (min)⁻¹. Coupling efficiency is the percentage of NADPH consumed which was utilised for product formation, i.e. a percentage of the theoretical maximum efficiency. The CYP102A1 enzyme of the invention (for example when used in the process of the invention) may typically have a coupling efficiency of at least 1%, such as at least 2%, 4%, 6%, 10%, 20%, 40%, 80% or more. The CYP102A1 enzyme (for example when used in the process of the invention) typically has a product formation rate of at least 2 min⁻¹, such as at least 4, 10, 15, 20, 25, 50, 100, 200, 300, 500, 700, 1000, 2000 min⁻¹ or more. Where more than one product is formed (which is commonly the case), the product formation rates represent the total amount of all oxidation products formed. In some embodiments, product formation rate of a specific oxidation product is measured, i.e. not all oxidation products may be measured.

The mutant CYP102A1 enzymes of the invention display an enhanced monooxygenase activity and/or an altered selectivity with respect to the corresponding wild type CYP102A1 enzyme. Enhanced monooxygenase activity may be characterised in terms of an increased coupling efficiency or an increased product formation rate with one or more substrates for oxidation. The increased coupling efficiency or increased product formation rate may or may not be shared across all substrates utilised by the mutant CYP102A1 enzyme. The mutant CYP102A1 enzymes typically display a coupling efficiency which is at least 10%, 20%, 50%, 100%, 500%, 1000% or 1500% greater than that of the wild type enzyme. The mutant CYP102A1 enzymes may also have a product formation rate which is at least 50%, 100%, 150%, 500%, 1000%, 2000%, 5000%, 10000% greater than that of the wild type enzyme.

It is to be understood that the mutant CYP102A1 enzymes of the invention may also display other altered characteristics with respect to the corresponding wild type enzyme and mutants disclosed in the literature, such that the effects may include, but may also not be limited to, enhanced monooxygenase activity. For example, the mutant enzyme may display an altered substrate specificity, allowing preferential utilization of specific substrates, or may display monooxygenase activity where the wild type enzyme or known mutants are not able to oxidize the substrate organic compound.

The mutant enzymes of the invention may also display altered product selectivity where a product formed in minor proportions by the wild type becomes the dominant product for the mutant, or new products formed in minor proportions or not at all by the wild type become the majority or dominant product. Further altered characteristics of the mutant enzymes and of the oxidation processes carried out by the mutant enzymes are described below.

The mutant CYP102A1 enzymes comprise a substitution at one or more of positions 117, 131, 191, 215, 276, 307, 330, 377, 401, 403, and 425 of CYP102A1. Typically, they may comprise substitutions at 2 or more, 3 or more, 4 or more, 5 or more, 6 or more of the positions defined above. In one preferred embodiment, where there is a substitution at position 330, there are less than 5 other substitutions, such as less than 3, or in one embodiment none of the other positions are substituted.

Where specific mutants of CYP102A1 are described, the letter of the amino acid residue present in the natural form of CYP102A1 is followed by the position, followed by the amino acid in the mutant. These positions can be correlated to the numbering shown in SEQ ID NO:1. To denote multiple mutations in the same protein each mutation is listed separated by slashes. Also, particularly preferred mutants may be described using internal denominations as outlined below.

While mutations are defined by reference to a position in CYP102A1, the invention also encompasses equivalent substitution mutations at a homologous or corresponding position in the polypeptide chain of a homologue of CYP102A1 which shares at least 40% amino acid identity to SEQ ID NO:1. An equivalent position is determined by reference to the amino acid sequence of SEQ ID NO:1. The homologous or corresponding position can be readily deduced by lining up the sequence of the homologue and the sequence of CYP102A1 (SEQ ID NO:1) based on the homology between the sequences. The PILEUP and BLAST algorithms can be used to line up the sequences. Where the homologous or corresponding amino acid referred to is an active site residue, it will generally be in a similar place in the active site of the homologue as any of the specific amino acids discussed herein.

Despite having a highly conserved tertiary structure, the P450 superfamily of enzymes is well known to those skilled in the art to be unusual among proteins and enzymes in having primary structures with low homology (35-37). There are now >6500 CYP genes in the genome databases, and >150 structures in the Protein Data Bank. All P450 structures determined to date show a characteristic topography incorporating a helix-rich domain packed against a mainly β strand domain, as described by Poulos and co-workers in the first reported crystal structure of a P450 enzyme (CYP101A1) (38). The helices are termed A-L, and the β strands β1-β5, with the overall topography now being known as the ‘P450 fold” (38-42). Of the secondary structural elements, the B and B′ helices, the BC loop, the F and G helices and the FG loop on the distal side of the haem form the substrate binding pocket. Sequence alignments readily identify residues within these helices and loops, but there is a high degree of variability within this general framework, both in terms of amino acid sequence and structural arrangement, and it is this that gives rise to the myriad specificity, activity and selectivity patterns of P450 catalysis.

P450 enzymes in different families have homologies (amino acid identities) as low as 20% (35-37). A sample of alignment between CYP102A1 and structurally characterized P450 enzymes is shown in Table A. Until recently, continued sequence analysis had suggested that as few as three residues out of typically 400-460 in P450 enzymes or domains were absolutely conserved: the proximal cysteine ligand to the haem iron, and the EXXR motif in the K helix that might play a role in haem association and binding (43). However, results on the CYP157 family published in 2006 showed that even the EXXR motif is not conserved, leaving the proximal cysteine as the only conserved residue across the whole P450 superfamily. In the systematic classification of the P450 superfamily (44), enzymes with just 40% amino acid identity are therefore placed within the same family, and closely related members of a family (>55% identity) are grouped into sub-families (see, for example, Table B).

It is in fact the detailed molecular structure, substrate specificity and product selectivity that are conserved within a family rather than sequence identity, which is often low. The most striking example is the CYP51 family of sterol 14α-demethylases that are found in all kingdoms of life. These play the pivotal role of oxidative demethylation of the C14 methyl group of intermediates formed after cyclization of squalene oxide. Sequence alignments showed that homology between known CYP51 family genes from across all kingdoms of life was on average 30%, rising as high as 95% in closely related species such as mammals and falling as low as 23% between lower organisms (45). It is increasingly recognized that the 40% cut-off for assigning enzymes to the same family could be too high in some instances, and that enzymatic activity and the higher homology often observed for active site residues may need to be taken more into consideration in future.

Thus, homologues that are typically at least 40% homologous to CYP102A1 on the basis of amino acid identity may also be readily identifiable on the basis of the “P450 fold”, and alignment of sequences of homologues to introduce an equivalent mutation at a corresponding or homologous position may be assisted by knowledge of the conserved nature of the arrangement of α helices and β strands that comprises the P450 fold shared throughout the enzyme family.

It is to be understood that CYP102A1 is a fusion of the electron transfer reductase domain and the haem monooxygenase domain. These domains may be cleaved proteolytically or by truncation of the full-length gene. The active site (substrate binding pocket) is located in the haem domain. Some members of the CYP102 family are not fusion proteins but the sequence homology with the CYP102A1 haem domain is 40%. Thus, sequence homology may be measured solely over the haem domain in these circumstances. Equivalent residues in these enzymes to those in CYP102A1 disclosed in the present invention can be identified by sequence homology and structural analysis known to those skilled in the art.

An amino acid in the active site is one which lines or defines the site in which the substrate is bound during catalysis or one which lines or defines a site through which the substrate must pass before reaching the catalytic site. Therefore such an amino acid typically interacts with the substrate during entry to the catalytic site or during catalysis. Such an interaction typically occurs through an electrostatic interaction (between charged or polar groups), hydrophobic interaction, hydrogen bonding or van der Waals forces. Active site amino acids can be identified by sequence alignment and reference to the known crystal structure of the haem domain of wild type CYP102A1, or the crystal structure of the homologues.

Where the mutated residue is not an active site residue, computerized or manual alignment of sequences of the homologue and of CYP102A1 is carried out to deduce the homologous or corresponding position, which may be assisted by knowledge of the residues flanking the mutated position in CYP102A1. Thus, for example, the 10 N-terminally and C-terminally flanking residues to the following positions in CYP102A1 are:

FSQQAMKGYH(A117)MMVDIAVQLV; DIAVQLVQKW(E131)RLNADEHIEV; LDEAMNKLQR(A191)NPDDPAYDEN; FQEDIKVMND(L215)VDKIIADRKA; HETTSGLLSF(A276)LYFLVKNPHV; VLVDPAPSYK(Q307)VKQLKTVGMV; EALRLWPTAP(A330)FSLYAKEDTV; GDDVEEFRP(E377)RFENPSAIPQ; KPFGNGQRAC(I401)GQQFALHEAT; FGNGQRACIG(Q403)QFALHEATLV; GMMLKHFDFE(D425)HTNYELDIKE

Conservation of 2, 3 or more of the N- and/or C-terminal flanking residues can allow for deduction of the homologous or corresponding position at which a mutation is to be introduced.

Similar analyses can be carried out for any other positions in CYP102A1 that are referred to in the description so as to identify the homologous or corresponding site in a naturally occurring homologue of CYP102A1.

Functional fragments of CYP102A1 enzymes are also encompassed in the present invention. These fragments may thus comprise only those amino acids which are required for oxidation activity. Thus, with reference to the polypeptide sequence of CYP102A1, the reductase domain and/or up to 20 residues at the N-terminal or C-terminal portion of the monooxygenase domain could be deleted without significantly affecting folding of the active site or the intrinsic substrate oxidation ability of the monooxygenase domain. In homologues of CYP102A1, similar truncations are possible, and the extent of truncation possible can be determined by methods for monitoring oxidation activity that are described herein. Truncated forms of the enzyme may possess advantageous properties in terms of stability, expression level, and activity of the protein.

The nature of the amino acid to be substituted at the positions of CYP102A1 described herein (or equivalent positions as defined above) is primarily determined by the requirement for the mutant to display an enhanced monooxygenase activity. Thus, an amino acid that is introduced will typically enhance monooxygenase activity. Where any reference is made to specific substitution mutations in CYP102A1, it is to be understood that any substitution of another amino acid residue at the same position which has effects which are redundant over, or similar to, the effect of the specific substitution mutation on the oxidation activity of the CYP102A1 enzyme, is encompassed according to the present invention. Similarly, where a specific substitution mutation also has an effect on another parameter of the CYP102A1 enzyme, such as substrate specificity, or the range or ratio of oxidation products obtained in oxidation of a given substrate, it is to be understood that substitutions of other amino acid residues that also elicit a redundant or similar effect are also contemplated for use according to the invention.

In some embodiments, the substitution introduces a conservative change, which replaces the amino acid with another amino acid of similar chemical structure, similar chemical properties or similar side-chain volume. The amino acids introduced may have similar polarity, hydrophilicity or hydrophobicity to the amino acids they replace. Conservative amino acid changes are well known in the art and may be selected in accordance with the changes defined in Table C. Where amino acids have similar polarity, this can also be determined by reference to the hydropathy scale for amino acid side chains (Table D).

Conservative amino acid changes may also be determined by reference to the Point Accepted Mutation (PAM) or BLOcks SUbstitution Matrix (BLOSUM) family of scoring matrices for conservation of amino acid sequence. Thus, conservative amino acid changes may be members of an equivalence group, being a set of amino acids having mutually positive scores in the similarity representation of the scoring matrix selected for use in an alignment of the reference and mutant polypeptide chains.

It is to be understood that the definitions of physical characteristics provided in Table C are not considered to be limiting on the invention and that non-polar amino acids include amino acids with aliphatic side chains and amino acids with aromatic side chains. The amino acid proline is classified as non-polar but it also has the property of being rigid and can cause changes in secondary structure. For example prolines are often found at the end of helices. Also, depending on the specific context of the side chain of a given amino acid residue, for example the amino acid tyrosine, generally classed as non-polar due to its aromatic ring, may have analogous functional effects to a polar amino acid residue such as threonine via its hydroxyl group. Thus, tyrosine may be considered to be both a non-polar and a polar amino acid for the purposes of the invention. Furthermore, amino acids which are described as polar or hydrophilic may be uncharged or charged, and may also be basic or acidic. The amino acid histidine is well known to have a pKa value near 7, so that at neutral pH depending upon the protein environment, it may or not be protonated on its side chain, and thus may or not carry a charge. Thus, histidine may be considered to be both a polar charged or a polar uncharged amino acid residue for the purposes of the invention.

Specific examples of conservative amino acid changes for positions 117, 131, 215, 307, 330, 401, and 403 in CYP102A1 (or equivalent positions thereto) include, but are not limited to:

A117V, A117I, A117L, A117P, A117M, A117F, A117W, A117Y;

E131D;

L215I, L215V, L215P, L215F, L215W, L215Y;

Q307H, Q307N, Q307S, Q307T, Q307Y;

A330P, A330I, A330L, A330M, A330V, A330F, A330W, A330Y;

I401P, I401I, I401L, I401M, I401V, I401F, I401W, I401Y;

Q403N, Q403H, Q403A, Q403T, Q403Y.

In other preferred embodiments, the amino acid substitution introduces a polar amino acid at a given position of the wild type enzyme, typically where the existing residue is a non-polar residue, thus changing polarity. Specific examples of polar amino acid substitutions for positions 191 and 276 in CYP102A1 (or equivalent positions thereto) include, but are not limited to:

A191T, A191S, A191C, A191Y, A191H, A191K; A191R, A191N, A191Q;

A276T, A276S, A276C, A276Y, A276H, A276K, A276R, A276N, A276Q.

Contrastingly, in other preferred embodiments, the amino acid substitution introduces a non-polar amino acid at a given position of the wild type enzyme, typically where the existing residue is a polar residue. For example, a non-polar amino acid may be introduced at position 377 or 403, or an equivalent position thereto. Specific examples include but are not limited to:

E377A, E377V, E377L, E377I, E377P, E377F, E377Y, E377W;

Q403P, Q403W, Q403F, Q403Y;

In a further embodiment, the amino acid substitution causes a charged side chain group to be lost at a given position of the wild type enzyme. Thus, the substitution introduces an uncharged amino acid at the relevant position. This may or may not lead to a loss of polarity at this position, such that either a polar uncharged or a non-polar (aromatic or aliphatic) residue is introduced. For example, a non-polar or a polar uncharged residue may be introduced at position 425, or at an equivalent position thereto. Specific examples include, but are not limited to:

D425N, D425Q, D425H, D425S, D425T, D425A, D425L, D425V, D425I, D425P, D425W, D425Y, D425F.

In still further embodiments, an amino acid of an increased side-chain volume is introduced at a position of the invention. In preferred embodiments, an amino acid of increased side-chain volume, typically a bulky non-polar amino acid is introduced at position 330, 401, 403 or at an equivalent position thereto. Particularly preferred substitutions for position 330 are A330P, A330V, A330L, A330I, A330W, A330F, A330Y. Particularly preferred substitutions for position 403 are Q403P, Q403W, Q403F. In other embodiments, for example at position 377, it may be preferred that the amino acid to be introduced has a reduced side-chain volume, such as E377A or E377G.

The mutations discussed herein are generally introduced into the enzyme by using methods known in the art, such as site directed mutagenesis of the enzyme, PCR and gene shuffling methods or by the use of multiple mutagenic oligonucleotides in cycles of site-directed mutagenesis. Thus the mutations may be introduced in a directed or random manner. The mutagenesis method thus produces one or more polynucleotides encoding one or more different mutants. Typically a library of mutant genes is produced which can be used to produce a library of mutant enzymes.

The enzyme may have 1, 2, 3, 4, 5 to 10, 10 to 20, 20 to 40 or more other mutations in addition to the one or more mutations specified above, such as substitutions, insertions or deletions. These additional mutations may or may not enhance monooxygenase activity of the mutant CYP102A1 enzyme. The other mutations may be in the active site or outside the active site. For example, the mutations may be in the second sphere, i.e. residues which affect or contact the position or orientation of one or more of the amino acids in the active site. An insertion will typically be N and/or C terminal. Thus the enzyme may contain a short peptide of up to 20 amino acids or a full-length protein fused to either or both of the termini, e.g. to aid protein purification by affinity chromatography or immobilisation on a solid matrix. A deletion typically comprises the deletion of amino acids which are not involved in catalysis, such as those outside the active site (thus the enzyme is a mutated fragment of a naturally occurring enzyme).

Other mutations in the active site typically alter the position and/or conformation of the substrate when it is bound in the active site. The mutations may make the site on the substrate which is to be oxidized more accessible to the haem group. Thus the mutations may be substitutions to an amino acid which has a smaller or larger, or more or less polar, side chain.

Additional mutations can include amino acid residue changes that can increase the stability of the enzyme. These mutations typically prevent oligomerisation of the protein, e.g. dimerisation of P450_(cam) (CYP101A1) has been removed by substitution of Cys344, preferably to alanine. The crystal structure of full-length CYP102A1 is not yet available, only those of the separate haem and FAD/FMN domains. A similar substitution is not necessary for CYP102A1 because Cys334 of CYP101A1 aligns with Asp370 in CYP102A1. However, the crystal structure of the full-length CYP102A1 and/or the reductase domain may reveal cysteine residues that may be removed by substitution with alanine to improve protein stability. Other mutations can also inhibit oligomerisation arising from contacts between hydrophobic patches on protein surfaces. Still further mutations include insertions/deletions that aid enzyme purification and/or immobilisation, and mutations that allow the protein to be prepared in soluble form, for example by the introduction of deletions or a poly-histidine tag, or by mutation of the N-terminal membrane anchoring sequence.

Preferably, the additional mutations are selected from one or more of the following mutations in CYP102A1: R47L, Y51F, A74G, A264G, N239H, I259V, L353I, F87A, F87L, F87G, H171L, L188Q, N319Y, I263A, A328P, or from the same mutations at equivalent positions thereto. It is also to be understood that the same considerations apply as outlined above in reference to positions 117, 131, 191, 215, 276, 307, 330, 377, 401, 403 and 425, in relation to selecting other amino acid changes that have redundant or similar effects to those specifically listed. Thus, for example, depending on whether the specific additional mutation listed above is a conservative change, changes polarity or introduces an uncharged amino acid, an analogous range of amino acids would be suitable for introduction at each additional position.

In particularly preferred embodiments, the mutant CYP102A1 enzymes of the invention comprise one or more groups of mutations selected from the following groups of mutations in CYP102A1:

-   -   i) A330P     -   ii) A191T/N239H/I259V/A276T/L353I;     -   iii) F87A/H171L/Q307H/N319Y;     -   iv) F87A/A330P/E377A/D425N;     -   v) F87A/A117V/E131D/L2151;     -   vi) I401P;     -   vii) R47L/Y51F/I401P;     -   viii) F87A/I401P;     -   ix) R47L/Y51F/F87A/I401P;     -   x) R47L/Y51F/A330P/I401P;     -   xi) Q403P;     -   xii) R47L/Y51F/Q403P;     -   xiii) R47L/Y51F/F87A/Q403P.         or comprise equivalent groups of mutations thereto.

The A330P mutation as defined in i) is an unusual mutant in several respects, as unlike other directed evolution variants whose effects may depend on a medley of altered residues acting in concert, its activity derives from a single point mutation. In CYP102A1, A330 lies next to a naturally occurring proline residue at position 329, and thus A330P juxtaposes two prolines at a primary substrate contact point in an area of β-sheet (3). The crystal structure of the mutant (FIG. 2) suggests that this constricts the access channel and makes the active site less accessible, thereby leading to a more closed active site and altering the binding configuration for substrates. As will be seen below, this has characteristic effects on monooxygenase activity and product selectivity.

Groups of mutations and iii) enhance the activity of CYP102A1, while broadly mirroring the specificity traits displayed by the wild type enzyme. With the exception of residue 87 in groups iii) to v), none of the positions mutated in any of the groups of mutations are active site residues.

For example in group ii), position 353 lies next to a substrate access channel residue 354, while residues 191, 239, 259, 276 and 353 are located at the protein surface. A191 is noticeably displaced on palmitate binding according to the crystal structure (4), and lies on the outer lip of the access channel. It is speculated that mutating this residue may have effects on substrate enticement and/or capture.

In group iii), position 171 is located on or close to the protein surface, while residues 307 and 319 are close to the region thought to be the docking site for the electron transfer reductase domain, and thus may potentially mediate its effects on enhancement of monooxygenase activity through influences on electron transfer kinetics.

Group of mutations iv) includes the A330P mutation at a substrate contact point, and mutations at positions 377 and 425 which are located peripherally in the enzyme structure close to the protein surface, as are positions 117, 131, and 215 in group of mutations v).

In still preferred embodiments, the mutant CYP102A1 enzymes of the invention of the classes defined above:

-   -   i) additionally comprise one or more of the following mutations         in CYP102A1: R47L, Y51F, A74G, A264G, or equivalent mutations         thereto;     -   ii) additionally comprise one or more of the following mutations         in CYP102A1: R47L, Y51F, F87A, F87L; and     -   iii) additionally comprise one or more of the following         mutations in CYP102A1: F87A, F87G, I259V, I263A.

It is to be understood that up to 1, 2, 3, 4, 5 to 10, 10 to 20 or more other mutations in addition to the specific mutations or specific additional mutations specified above may also be included in these preferred embodiments of the mutant CYP102A1 enzymes of the invention.

The substrate for the oxidation process is any organic compound, more typically any organic compound capable of being oxidized by a monooxygenase enzyme. The suitability of any organic compound for oxidation by a monooxygenase enzyme may be routinely determined by the methods described herein. The oxidation process causes the formation of a C—O bond in the compound, generally as the alcohol from the oxidation of a carbon-hydrogen bond, but an epoxide may be formed from the oxidation of a C═C bond. The oxidation may thus introduce an alcohol, aldehyde, ketone or epoxide group. Alternatively the oxidation may cause the further oxidation of an oxygen containing group, such as converting an alcohol group into an aldehyde or ketone. 1, 2 or more carbon atoms may be attacked in the same substrate molecule. Oxidation can also result in N- and O-dealkylation of the substrate molecule.

The oxidation typically gives rise to 1, 2 or more oxidation products. These different products may result from different carbon atoms being attacked and/or from different degrees of oxidation occurring at a given carbon atom.

The oxidation may occur on either a ring carbon atom or a substituent carbon atom or both. At least the initial oxidation will involve attack of a C—H bond which may be activated or non-activated or attack at a carbon-carbon double bond (typically giving an epoxide). Generally an activated C—H bond is where the carbon atom is in a benzylic or allylic position. Aromatic rings and olefinic double bonds activate C—H bonds to attack by stabilising the radical intermediate or any build-up of charge generated during the reaction pathway. The carbon of the C—H bond may be primary, secondary or tertiary. The oxidation may occur to result in dehydrogenation leading to a C═C double bond formation rather than insertion of an oxygen atom. This is most likely to occur when the alkyl substituent is branched, or dehydrogenation leads to a C═C bond that is conjugated to an aromatic system, or dehydrogenation leads to the formation of an aromatic system.

The substrate can either be a natural substrate of a wild type CYP102A1 enzyme or a substrate which is not normally a substrate for the wild type enzyme, but which is capable of being utilized as such in the mutant enzyme. Examples of natural substrates for the CYP102A1 enzymes are branched and straight chain fatty acids, which are hydroxylated by wild type CYP102A1 at sub-terminal positions (ω-1 to ω-3). Preferred examples are lauric acid, undecanoic acid, decanoic acid, nonanoic acid and octanoic acid.

In preferred embodiments, the substrate is a short-chain alkane or a medium-chain alkane or an alkylbenzene. The term alkane refers to acyclic branched or unbranched hydrocarbons having the general formula C_(n)H_(2n+2).

A short-chain alkane has typically from 1 to about 9 carbon atoms, more preferably 1 to 8, 1 to 6, or 1 to 4 carbon atoms. A C₁-C₈ alkyl group or moiety can be linear or branched. Where it is a C₁-C₄ alkyl moiety, it can be, for example, methyl, ethyl, n-propyl, i-propyl, sec-butyl and t-butyl.

An alkylbenzene has one or more alkyl groups or moieties substituted at positions on the benzyl aromatic ring. The numbers of carbon atoms in the alkyl groups or moieties can be typically from 1 to about 8 carbon atoms, more preferably 1 to 8, 1 to 6, or 1 to 4 carbon atoms.

In some embodiments there may be 1, 2, 3 or more substituents present on the backbone of the short-chain or medium-chain alkane or directly substituted on the benzyl ring, or on the alkyl substituent of the alkylbenzene. Any combination of the following substituents may be present. The substituent is typically a halogen atom or an alkyl or alkenyl group, which generally has 1 to 6 carbons, the substituent optionally being substituted with one or more halogens. The substituent may also comprise 1, 2 or more oxygen, halogen or nitrogen atoms and for example may be an alcohol, aldehyde, ketone, ether, amine or epoxide group.

Examples of preferred short-chain alkane substrates include, but are not limited to pentane, 3-methylpentane, 2-methylbutane, butane, propane, ethane and methane, octane and nonane. Examples of preferred alkylbenzene substrates include, but are not limited to propylbenzene, ethylbenzene, butylbenzene, cumene, t-butylbenzene, o-xylene, m-xylene, p-cymene and ethylanisole. Other preferred aromatic compounds are naphthalene and fluorene.

It is to be noted that organic compounds such as butane, naphthalene, and in particular, propane, t-butylbenzene and o-xylene are broadly classified as “non-natural” substrates for the wild type CYP102A1 enzyme, but are capable of being oxidized by the mutant CYP102A1 enzymes of the invention. A non-natural substrate can be defined as a molecule which has no detectable coupling rate and/or product formation when incubated with the wild type CYP102A1. Non-natural substrates may also include molecules which are oxidized at <10% of the rate for a natural substrate by the wild type CYP102A1 enzyme such that they may not be regarded as a bona fide substrate.

In other embodiments of the invention, the substrate is a terpene, for example a monoterpene, or a sesquiterpene. The substrate can also be a cycloalkene. Although the terpenes used in the present invention will generally have the formula (C₅H₈)_(n) where n is 2 or more, especially 2 or 3, it is to be understood that the term “a terpene” extends to compounds which are strictly referred to as “a terpenoid”, involving the loss or shift of a fragment, generally a methyl group. Thus, for example, sesquiterpenes (where n is 3) which can be used in the present invention may contain only, say, 14, rather than 15, carbon atoms. Generally the terpene is one which can be built up from isoprene units. The terpene may be cyclic or acyclic. It is moreover understood that a “terpenoid” also extends to compounds that are related to terpenes and may contain one or more oxygen atom, for example in the form of an alcohol or a ketone group, such as damascones and ionones, in particular β-ionone.

The monoterpenes (where n is 2) will generally have 10 carbon atoms, typically with 1 to 3 double bonds, especially 1 or 2 ring double bonds, and typically with 0 to 2 rings. It is possible for one of the rings to be formed as a bridge containing, typically 0 or 1 carbon atoms. In other words, it can be formed by a direct link between 2 carbon atoms of an existing ring or with an intermediate methylene group. If the terpene is acyclic it will generally contain at least 2 double bonds and generally 3.

The sesquiterpenes will normally contain 14 or 15 carbon atoms, typically with 0 to 2 double bonds and typically 1 to 3 rings, with the possibility of fused rings and/or bridged rings.

The rings which may be present in the terpenes will typically have from 3 to 9 carbon atoms, more especially 5 or 6 carbon atoms. Thus, in particular, the terpenes will contain a cyclohexane, or cyclohexadiene ring.

The terpenes will generally contain a total of 3 or 4 exocyclic methyl or methylene groups, for example 2 methyl groups and 1 methylene group or 3 methyl groups for a monoterpene, and 3 methyl groups and 1 methylene group or 4 methyl groups for a sesquiterpene.

The monoterpene is typically a limonene such as R-limonene, a pinene such as (+)-α-pinene, terpinene, sabinene, thujene, myrcene, ocimeme, nerol or geraniol.

The sesquiterpene is generally formed by a head-to-tail arrangement of three isoprene units. The sesquiterpene is typically an aromadendrene, caryophyllene, longifolene, valencene, isobazzanene, silphinene, ishwarane, isopatchchoul-3-ene, or isosesquicarene. It is particularly preferred that the sesquiterpene substrate be valencene.

The cycloalkene generally comprises up to 9 ring members, e.g. it is a 5, 6, 7, 8, 9 or more membered ring. The cycloalkene is typically a cyclohexene.

Substituted derivatives of any of the terpenes or cycloalkenes mentioned above may also be used. Typically 1, 2, 3 or more substituents are present. Any combination of the following substituents may be present. The substituent is typically a halogen atom or an oxygen or nitrogen containing group or an alkyl or alkenyl group, which generally has 1 to 6 carbons, the substituent optionally being substituted with one or more halogens.

The substituent typically has the formula C_(n)H_(k)X_(m), wherein X is the halogen, oxygen or nitrogen containing group, n is 1, 2, 3 or more, m is 1, 2, 3, 4 or more and k is an integer which has an appropriate value so that the valencies of the substituent C_(n)H_(k)X_(m) are satisfied. For an alkyl substituent k+m=2n+1. Typically k is 1, 2, 3, 4 or more, or may be 0, i.e. the substituent is a perhaloalkyl group. The halogen is typically fluorine, chlorine or bromine. The substituent may also comprise 1, 2 or more oxygen atoms and for example may be an alcohol, aldehyde, ketone or epoxide group.

In further embodiments of the invention, the substrate is a halo aromatic compound. The halo aromatic compound is typically a benzene or biphenyl compound. The benzene ring is optionally fused and can be substituted. The halogen is typically chlorine. In many cases there is more than one halogen atom in the molecule, typically 2 to 5 or 6, for example 3. Generally 2 of the halogen atoms will be ortho or para to one another. The compound may or may not contain an oxygen atom such as a hydroxy group, an aryloxy group or a carboxy group. The compound may or may not be chlorophenol or a chlorophenoxyacetic acid compound.

Specific compounds which could be oxidized by the process of the present invention include 1,2-; 1,3- and 1,4-dichlorobenzene, 1,2,4-; 1,2,3- and 1,3,5-trichlorobenzene, 1,2,4,5- and 1,2,3,5-tetrachlorobenzene, pentachlorobenzene, hexachlorobenzene, and 3,3′-dichlorobiphenyl.

Other compounds which could be oxidized by the process include recalcitrant halo aromatic compounds, especially dioxins and halogenated dibenzofurans, and the corresponding compounds where one or both oxygen atoms is/are replaced by sulphur, in particular compounds of the dioxin class which possess at least one halo substituent, such as dioxin itself, 2,3,7,8-tetrachlorodibenzodioxin.

The oxidation of halo aromatic compounds typically gives rise to 1, 2 or more oxidation products. The atom which is oxidized may be a ring carbon. These oxidation products will generally comprise 1 or more hydroxyl groups. Generally, therefore, the oxidation products are phenols which can readily be degraded by a variety of Pseudomonads and other bacteria, whereas the unoxidized halo aromatic compounds are refractory to oxidation. As described below, this makes the enzyme of the invention suitable for decontamination of a locus contaminated with a halo aromatic compound.

Still further substrates contemplated for use in the processes of the invention include, but are not limited to chloraoxazone, aniline, p-nitrophenol, nifedipine, thujone diastereomers, alkenes (including propene, 1-hexene and styrene), indole, polycyclic aromatic hydrocarbons, propanolol, alkoxyresorufins (including 7-ethoxyresorufin, 7-methoxyresomfin, 7-penthoxyresorufin, 7-benzyloxyresorufin), buspirone, testosterone, amodiaquine, dextromethorphan, acetaminophen, 3,4-methylenedioxymethylamphetamine (MDMA).

The oxidation process carried out with a mutant CYP102A1 enzyme of the present invention may be differentiated from that carried out by another wild type or mutant CYP102A1 enzyme in terms of an improved coupling rate or rate of product formation, as defined above. The processes of the invention may also be characterized by formation of a specific product from the oxidized substrate, typically one which is not formed by the wild type CYP102A1 enzyme or another mutant CYP102A1 enzyme, or one which is formed in negligible quantities, i.e. less than 10%, 8%, 5%, 2%, 1% or less of the total amount of product. For example, oxidation of propylbenzene may produce 2-propylphenol, or 1-phenyl-2-propanol with high selectivity, or oxidation of ethylbenzene may produce 2-phenylethanol and styrene.

Processes carried out with the mutant CYP102A1 enzyme of the invention may also display an altered ratio or number of oxidation products, as compared to the oxidation process carried out by a wild type CYP102A1 enzyme or other mutant CYP102A1 enzyme. Where an altered ratio of products is present, the product formation rate for a specific oxidation product is typically increased with reference to the corresponding process carried out by a wild type CYP102A1 enzyme or other mutant CYP102A1 enzymes. The increase in the prevalence of a specific oxidation product may be at least 10%, 20%, 50%, more preferably 100%, 200%, 300%, 500% or more over the amount of said oxidation product in the product mixture as formed by the wild type CYP102A1 enzyme or other mutant CYP102A1 enzymes.

Specific examples of oxidation products that may show increased prevalence in the processes of the invention include: i) 1-phenyl-2-propanol, wherein the oxidized substrate is propylbenzene; ii) 2-ethylphenol, wherein the oxidized substrate is ethylbenzene; iii) 1-phenyl-2-butanol or 4-phenyl-2-butanol, wherein the oxidized substrate is butylbenzene; iv) benzylalcohol, wherein the oxidized substrate is toluene; v) 2-methyl-2-phenylpropan-1-ol, wherein the oxidized substrate is t-butylbenzene; vi) 2-methylbenzylalcohol, wherein the oxidized substrate is o-xylene; vii) carvacrol or thymol or 4-isopropylbenzylalcohol, wherein the oxidized substrate is p-cymene; viii) nootkatone, wherein the oxidized substrate is valencene; ix) 2-nonanol, wherein the oxidized substrate is nonane; x) 2-butanone or 2-butanol, wherein the oxidized substrate is butane; xi) 3-methyl-3-pentanol, wherein the oxidized substrate is 3-methylpentane; 2-propanol, wherein the oxidized substrate is propane; xiii) trans-isopiperitenol, wherein the oxidized substrate is R-limonene; xiv) 2,3-pinene epoxide, cis-verbenol, trans-verbenol, wherein the oxidized substrate is a-pinene; xv) 9-fluorenol, wherein the oxidized substrate is fluorene; xvi) 8-hydroxydodecanoic acid and 7-hydroxydodecanoic acid, wherein the oxidized substrate is lauric acid.

The process is typically carried out in the presence of the CYP102A1 enzyme, the substrate and the natural co-factors of the enzyme which are NADPH and dioxygen. In one embodiment the process is carried out with an enzyme such as a dehydrogenase and its co-substrate to regenerate the NADPH from NADP⁺ with concomitant oxidation of the co-substrate of the dehydrogenase enzyme. In another embodiment the process is carried out by regenerating the NADPH co-factor by electrochemical methods known to those in the art.

It is understood that the increased activity and altered selectivity arise from substitutions in the haem domain of the CYP102A1 enzyme. The present invention therefore also provides for systems in which the substrate oxidation process is carried out in the presence of the haem domain of the enzyme (a), the substrate, an electron transfer reductase (b), an electron transfer redoxin (c), co-factor for the enzyme and an oxygen donor. In this system the flow of electrons is generally: co-factor→(b)→(c)→(a).

(b) is generally an electron transfer reductase which is able to mediate the transfer of electrons from the co-factor to (c), such as a naturally occurring reductase or a protein which has homology with a naturally occurring reductase, typically having at least 70% homology; or a fragment of the reductase or homologue. (b) is typically a reductase of any electron transfer chain found in naturally occurring P450 enzyme systems, and is typically a flavin dependent reductase, such as putidaredoxin reductase.

(c) is generally an electron transfer redoxin which is able to mediate the transfer of electrons from the co-factor to (a) via (b). (c) is typically a naturally occurring electron transfer redoxin or a protein which has homology with a naturally occurring electron transfer redoxin, typically having at least at least 70% homology; or a fragment of the redoxin or homologue. (c) is typically a redoxin of any electron transfer chain found in naturally occurring P450 enzyme systems. (c) is typically a 2Fe-2S redoxin, such as putidaredoxin, or a flavodoxin

Typically (a), (b) and (c) are present as separate proteins; however they may be present in the same fusion protein. Typically only two of them, preferably (b) and (c), are present in the fusion protein. Typically these components are contiguous in the fusion protein and there is no linker peptide present.

Alternatively a linker may be present between the components. The linker generally comprises amino acids that do not have bulky side chains and therefore do not obstruct the folding of the protein subunits. Preferably the amino acids in the linker are uncharged. Preferred amino acids in the linker are glycine, serine, alanine or threonine. In one embodiment the linker comprises the sequence N-Thr-Asp-Gly-Gly-Ser-Ser-Ser-C. The linker is typically from at least 5 amino acids long, such as at least 10, 30 or 50 or more amino acids long.

In the process the concentration of the enzyme, (b) or (c) is typically from 10⁻⁸ to 10⁻²M, preferably from 10⁻⁷ to 10⁻⁴M. Generally the process is carried out at a temperature and/or pH at which the enzyme is functional, such as when the enzyme has at least 20%, 50%, 80% or more of peak activity. Typically the pH is from 3 to 11, such as 5 to 9 or 6 to 8, preferably 7 to 7.8 or 7.4. Typically the temperature is 10° C. to 90° C., such as 25° C. to 75° C. or 30° C. to 60° C.

In the process more than one different mutant CYP102A1 enzyme of the invention may be present. Typically each mutant will be able to oxidize different substrates or may be able to oxidize a given substrate better than another enzyme, and thus using a mixture of mutant CYP102A1 enzymes will enable a wider range of substrates to be oxidized. The process may also include wild type CYP102A1 enzymes, other P450 enzymes or their homologues, any monooxygenase enzyme, and any other enzyme useful in the desired synthesis or oxidation reaction.

In one embodiment the process is carried out in the presence of a substance able to remove hydrogen peroxide by-product (e.g. a catalase). In another embodiment the process is carried out in the presence of the full-length enzyme or the haem domain of the enzyme, substrate and an oxygen atom donor, such as hydrogen peroxide or t-butylhydroperoxide, for example using the peroxide shunt.

In a further embodiment, the process is carried out in the presence of the full-length enzyme or only the haem domain of the enzyme, substrate and oxygen in an electrochemical cell such that the two electrons required for oxygen activation and generation of the active intermediate are supplied by the electrode, either by direct electron transfer from the electrode or indirectly via a small molecule mediator.

The process may be carried out inside or outside a cell. The cell is typically in culture, at a locus, in vivo or in planta (these aspects are discussed below). The process is typically carried out at a locus such as in land (e.g. in soil) or in water (e.g. fresh water or sea water). When it is carried out in culture the culture typically comprises different types of cells of the invention, for example expressing different mutant CYP102A1 enzymes of the invention. Generally such cells are cultured in the presence of assimilable carbon and nitrogen sources.

Typically the cell in which the process is carried out is one in which the mutant CYP102A1 of the invention, or wild type CYP102A1 does not naturally occur. In another embodiment the mutant CYP102A1 enzyme is expressed in a cell in which wild type CYP102A1 does naturally occur, but at higher levels than naturally occurring levels. The cell may produce 1, 2, 3, 4 or more different mutant CYP102A1 enzymes of the invention. These mutant CYP102A1 enzymes may be capable of oxidising different organic compound substrates, different short-chain alkanes or different alkylbenzenes.

The cell may be prokaryotic or eukaryotic and is generally any of the cells or of any of the organisms mentioned herein. Preferred cells are Escherichia coli, Pseudomonas sp., flavobacteria or fungi cells (e.g. Aspergillus and yeast, especially Pichia sp.). Also contemplated for use according to the invention are Rhodococcus sp. and Bacillus sp. The cell may or not be one which in its naturally occurring form is able to oxidize any of the substrates or generate any of the oxidation products mentioned herein. Typically the cell is in a substantially isolated form and/or substantially purified form, in which case it will generally comprise at least 90%, e.g. at least 95%, 98% or 99% of the cells or dry mass of the preparation.

The cell is typically produced by introducing into a cell (i.e. transforming the cell with) a vector comprising a polynucleotide that encodes the mutant CYP102A1 enzyme of the invention. It is to be understood that due to the degeneracy of the nucleotide code, more than one polynucleotide can encode each of the mutant CYP102A1 enzymes of the invention. It is also to be understood that the nucleotide sequence may be engineered to exhibit a codon bias suitable for a particular cell or organism. The vector may integrate into the genome of the cell or remain extra-chromosomal. The cell may develop into the animal or plant discussed below. Typically the coding sequence of the polynucleotide is operably linked to a control sequence which is capable of providing for the expression of the coding sequence by the host cell. The control sequence is generally a promoter, typically of the cell in which the monooxygenase is expressed.

The term “operably linked” refers to a juxtaposition wherein the components described are in a relationship permitting them to function in their intended manner. A control sequence “operably linked” to a coding sequence is ligated in such a way that expression of the coding sequence is achieved under conditions compatible with the control sequences.

The vector is typically a transposon, plasmid, virus or phage vector. It typically comprises an origin of replication. It typically comprises one or more selectable marker genes, for example an ampicillin resistance gene in the case of a bacterial plasmid. The vector is typically introduced into host cells using conventional techniques including calcium phosphate precipitation, DEAE-dextran transfection, or electroporation.

The invention further provides a transgenic animal or plant whose cells are any of the cells of the invention. The animal or plant is transgenic for one or more mutant CYP102A1 gene(s). They may be a homozygote or a heterozygote for such genes, which are typically transiently introduced into the cells, or stably integrated (e.g. in the genome). The animal is typically a worm (e.g. earthworm) or a nematode. The plant or animal may be obtained by transforming an appropriate cell (e.g. embryo stem cell, callus or germ cell), fertilizing the cell if required, allowing the cell to develop into the animal or plant and breeding the animal or plant if required. The animal or plant may be obtained by sexual or asexual reproduction (e.g. cloning), propagation of an animal or plant of the invention or of the F1 organism (or any generation removed from the F1, or the chimera that develops from the transformed cell).

As discussed above the process may be carried out at a locus. Thus the invention also provides a method of treating a locus contaminated with a substrate of the invention, for example a short chain alkane, an alkylbenzene or a halo aromatic compound. The method comprises contacting the locus with a mutant CYP102A1 enzyme, cell, animal or plant of the invention. These organisms are then typically allowed to oxidize the halo aromatic compound. In one embodiment the organisms used to treat the locus are native to the locus. Thus they may be obtained from the locus (e.g. after contamination), transformed/transfected (as discussed above) to express the mutant CYP102A1 (and optionally an appropriate electron transfer reductase and/or redoxin).

In one embodiment the locus is treated with more than one type of organism of the invention, e.g. with 2, 3, 4, or more types which express different monooxygenases which oxidize different organic compound substrates, for example different short chain alkanes, alkylbenzenes or halo aromatic compounds. In one embodiment such a collection of organisms between them is able to oxidize all substrates of a specific group, i.e. short chain alkanes that are present in the contaminated area.

The organisms (e.g. in the form of the collection) may carry out the process of the invention in a bioreactor (e.g. in which they are present in immobilised form). Thus the water or soil to be treated may be passed through such a bioreactor. Soil may be washed with water augmented with surfactants or ethanol and then introduced into the bioreactor.

Screening Design/Isolation of Mutants of the Invention

The methods disclosed to date for screening libraries of CYP102A1 mutants generated by random mutagenesis and gene shuffling have tended to use surrogate substrates such as indole (indigo formation) and p-nitrophenol derivatives (detection of p-nitrophenol released). Some of the selected mutants with enhanced oxidation activity for the surrogate substrate have been found to possess enhanced activity towards compounds with different structures but product selectivity changes are less common.

As regards screens for product selectivity, WO2006105082 disclosed a method for conjugating the product alcohol to a compound that can be detected spectroscopically. Similarly, increased selectivity for 1-octanol in octane oxidation by CYP102A3 was obtained by targeting this product in a dehydrogenase screening procedure (34). These approaches bias the search towards selectivity, with smaller increases in activity. Also, only those mutations that promote the formation of the specific target compound are found, while mutations at sites that affect product selectivity in different and potentially desirable manners towards a wider range of compounds are not revealed.

In contrast, the screening method used to isolate mutants according to the present invention utilizes a combination of screening a random library of mutants for indigo formation via indole oxidation followed by searching for enhanced activity and selectivity for products of chemical interest. Thus the most active mutants from the indole oxidation screen were further screened via in vivo oxidation of naphthalene, propylbenzene and octane. The products were analyzed by gas-liquid chromatography (see Examples section). Naphthalene is more hydrophobic than indole and more closely resembles the hydrocarbon substrates often targeted in P450 catalysis. Propylbenzene is smaller than naphthalene but poses a test for product selectivity changes because of competition between aromatic ring oxidation, benzylic oxidation, and attack at the two non-activated aliphatic carbon centers. Octane presents a different challenge being flexible and less compact, and having four different sets of C—H bonds available for oxidation, inviting mutations that bias selectivity towards terminal and internal positions. Variants with increased product formation rates and/or altered product profiles were selected for activity studies in vitro.

In this multi-step procedure ˜1,500 colonies were screened in the initial indigo formation (activity) step, which number was reduced to ˜800 colonies after gene shuffling of 11 of the first generation of mutants. 130 colonies out of these 800 were taken forward to the in vivo substrate oxidation screening steps. Of these 130, 5 variants were selected for further studies in vitro, all of which showed increased activity and/or altered product selectivity towards a broad range of organic compounds, from naphthalene to pentane. Thus, the screening method used to isolate mutants according to the present invention allows for efficient, stringent selection of mutants with increased activity and/or product selectivity. The small size of the initial library that was screened in the discovery of the mutations also indicates that the approach used by the Inventors for discovery of variants of CYP102A1 has yet to exhaust its potential.

A further difference to previously disclosed directed evolution techniques was that screening on CYP102A1 using indigo formation involved mutagenesis at specific sites (e.g. site saturation) in the CYP102A1 haem domain, whereas the present screening involved random mutagenesis of the full-length haem domain gene. Thus, the screen has the potential to isolate increased numbers of variants. Furthermore, it is clear that site-saturation mutagenesis could be applied to specific mutants isolated in accordance with the present invention so as to isolate further useful variants.

Examples Materials and Methods

General reagents and chemical substrates of analytical grade or higher quality were from Alfa-Aesar, Fisher Scientific and Sigma-Aldrich or their subsidiary companies. Solvents of HPLC quality were from Rathburn Chemicals (UK) and subsidiaries of Sigma-Aldrich and Merck. Buffer components were from Anachem, UK. NADPH (tetrasodium salt) was from Apollo Scientific and Melford Laboratories. Isopropyl-β-D-thiogalactopyranoside (IPTG) was from Melford Laboratories. Restriction enzymes, T4 DNA ligase and the related buffers were from New England Biolabs. Taq and KOD Polymerases were from Merck Biosciences. Competent and supercompetent E. coli strains were from Stratagene. Site-directed mutagenesis was carried out using the PCR method described in the Stratagene Quik-Change mutagenesis kit. The appropriate lengths of oligonucleotide flanking the altered codon in the mutagenic oligonucleotides were designed following the manufacturers' instructions. Oligonucleotides were from MWG Biotech. General molecular biology manipulations were carried out according to literature methods (Sambrook, J., Fritsch, E. F., and Maniatis, T. (1989) Molecular Cloning: A Laboratory Manual, 2^(nd) Ed., Cold Spring Harbor Laboratory Press, New York). All mutant genes were fully sequenced on an automated ABI 377XL Prism DNA sequencer by the facility at the Department of Biochemistry, University of Oxford. UV/visible spectra and enzyme activity assays were run at 30° C. on a Varian Cary 50 spectrophotometer. ¹H NMR spectra were acquired on a Varian UnityPlus 500 MHz spectrometer. Gas chromatography (GC) was carried out on Thermo Finnigan Trace and 8000 Top instruments equipped with flame-ionisation detectors (FIDs) using DB-1 fused silica capillary columns and helium as the carrier gas. The injectors were maintained at 200° C. or 250° C. and the FIDs at 250° C.

Mutagenesis, Design, Directed Evolution and Screening Procedures

A SpeI restriction site was introduced downstream of the pGLW11 haem domain-coding region (13) of the CYP102A1 gene using oligonucleotide:

5′ GCTCATAATACGCCGCTACTAGTGCTATACGGTTCAAATATG-3′ (the SpeI recognition sequence underlined) and its reverse complement, resulting in silent mutations at residues 482 and 483.

Error-prone PCR was carried out between this site and an EcoRI site upstream of the haem domain-coding region using the forward and reverse primers:

5′ TCTCGAGAATTCATAATCATCGGAGACGCC-3′ (the EcoRI recognition sequence underlined); and

5′-TGGATCCACTAGTAGCGGCGTATTATGAGC-3′ (the SpeI recognition sequence underlined).

Libraries were constructed from wild type CYP102A1 (WT) and mutant F87A templates under conditions designed to introduce 1-3 mutations per 1,000 by according to the Stratagene GeneMorph protocol employed. Genes were amplified by 30 cycles of strand separation at 94° C. for 60 s, annealing at 45° C. for 90 s and extension at 68° C. for 110 s+2 s per cycle. After digestion with EcoRI and SpeI, short fragments were reincorporated into pGLW11 (SpeI WT variant) using T4 DNA Ligase, transformed into E. coli DH5α competent cells and grown for 36 h on Luria-Bertani (LB) agar plates.

Around 1500 colonies were screened. Those showing indigo formation (Gillam, E. M. J. et al (1999) Biochem. Biophys. Res. Commun. 265, 469-472; Li, Q. S., et al (2000) Chem. Eur. J. 6, 1531-1536) were isolated, transferred to fresh plates and grown for a further 36 h to minimise false positives prior to sequencing. 11 variants representing 16 new mutations of potential interest were then shuffled by random-priming recombination (Shao, Z., et al (1998) Nucleic Acids Res. 26, 681-683).

The protocol given by Volkov and Arnold (Volkov, A. A., and Arnold, F. H. (2000) Methods Enzymol. 328, 447-456) was modified at stage 9, where Taq and KOD Polymerases were employed with 2 μL MgSO₄ rather than Pfu Polymerase. PCR was carried out on the assembly strands as described above, but using KOD Polymerase. Samples were digested, ligated and plated out as before.

Of ˜800 colonies, some 130 displayed indigo formation. These were grown up on a 5-10 mL scale and screened in vivo for naphthalene and propylbenzene oxidation activity using gas chromatography. The 12 variants that showed the largest increases in the product peak areas or altered product profiles compared to WT were sequenced, grown up on a larger scale and screened against the same two substrates. Of these, 5 were selected for studies in vitro.

We also prepared various single-site mutants and combinations thereof with the 5 mutants from the random mutagenesis screening procedure and examined these in vivo for indigo formation and for naphthalene, propylbenzene and octane oxidation activity using gas chromatography. The single-site mutations were R47L, Y51F, E267V, I263A, A74G, L188Q, M177V/K, A399P, I401P, G402P, Q403P, V302I, A264G, A99T, S270I, R179H, and F87L/A/G. The majority of these were previously known mutations (at R47, Y51, I263, A74, L188, M177, A264, F87) or ones we found in earlier rounds of the random mutagenesis/screening procedure (at E267, V302, A99, S270, R179) that were chosen for another round on the basis of their location in the structure being likely to have some effect on substrate binding. The proline mutations at A399, I401, G402 and Q403 were chosen based on the structural changes observed in the crystal structure of the A330P mutant (FIG. 2), one of the five mutants selected from the screening procedure. These mutants were then also screened by the in vivo screen method for evidence of increased activity.

The R47L and Y51F mutations, either on their own or when combined with other mutations, were not as effective as the R47L/Y51F couplet. The other single-site mutations showed different effectiveness in the indigo formation screen, while the I401P and Q403P single site mutants showed increased product formation over the wild type in the in vivo oxidation screen and these mutants were prepared and their activity studied in vitro. Variants R47L/Y51F (RLYF) and F87A were prepared as described (13). The RLYF couplet was introduced into variants KT2 and A330P using NcoI and AflII restriction sites in standard cloning procedures (Sambrook, J., Fritsch, E. F., and Maniatis, T. (1989) Molecular Cloning: A Laboratory Manual, 2^(nd) Ed., Cold Spring Harbor Laboratory Press, New York). The F87A mutation was introduced to the KT2, I401P, RYLF/I401P, and RYLF/Q403P variants by site-directed mutagenesis. The I401P and Q403P mutation were introduced to the RLYF and RLYF/A330P variants by site-directed mutagenesis.

Protein Expression and Purification

Variants of interest were transferred into the pET28 vector using NcoI and BamHI restriction sites so that expression levels could be more tightly controlled with the T7 promoter over the tac promoter in the pGLW11 vector. 30 ml.L⁻¹ of an overnight culture of E. coli JM109(DE3) harbouring the plasmid was inoculated into LB medium containing 0.4% (v/v) glycerol and 30 mg.L⁻¹ kanamycin and grown at 37° C. with shaking at 180 rpm to an OD₆₀₀ of >1. Protein expression was induced by adding isopropyl-β-D-thiogalactopyranoside (IPTG) to 0.4 mM. The temperature was lowered to 30° C. and after a further 12 h of growth at 30° C. cells were harvested by centrifugation. The red-brown pellet from each 1 L growth was re-suspended in 25 mL 40 mM potassium phosphate buffered at pH 7.4, 1 mM in dithiothreitol (phosphate buffer). The cells were lysed by sonication, and cell debris was cleared by centrifugation at 37,500 g for 30 min at 4° C. The supernatant was loaded onto an Amersham-Pharmacia DEAE fast flow Sepharose column (200×50 mm) pre-equilibrated with phosphate buffer from which the protein was eluted using a linear gradient of 80-400 mM ammonium sulphate in phosphate buffer. The red P450 fractions were collected and concentrated by ultrafiltration, desalted using a Sephadex G-25 column pre-equilibrated with phosphate buffer, and re-concentrated by ultrafiltration. The solution was centrifuged at 9,250 g for 5 min at 4° C. and filter sterilised. FPLC anion-exchange purification was carried out on an Amersham-Pharmacia Source-Q column (120×26 mm) using a linear gradient of 0-30% 15× phosphate buffer. Fractions with A₄₁₈/A₂₈₀>0.35 were collected, concentrated by ultrafiltration and filter sterilised before being stored at −20° C. in 50% (v/v) glycerol. Glycerol and salts were removed from proteins immediately prior to experiments using an Amersham Pharmacia 5 ml PD-10 column pre-equilibrated with 50 mM Tris buffer at pH 7.4.

NADPH Turnover Rate Determinations

NADPH turnovers (except butane and propane) were run in 1250 μL of 50 mM Tris (pH 7.4) oxygenated at 30° C. and containing 0.1 or 0.25 μM enzyme, 125 μg bovine liver catalase and 1 mM substrate added as a 100 mM stock in DMSO. Protein concentration was determined as described (13) or via CO-difference spectra (Omura, T and Sato, R (1964) J. Biol. Chem, 239, 2379-85). Assays were held at 30° C. for 1 min prior to NADPH addition as a 20 mg.ml⁻¹ stock to a final concentration of ˜160 μM or ˜320 μM (equivalent to 1 or 2AU). In butane and propane turnovers, substrate was bubbled into 3000 μL of Tris on ice for a minimum of 30 minutes while oxygen was bubbled into 1000 μL of Tris, also on ice. CYP102A1 (0.25 μM) and catalase (concentration as above) were added gently to the oxygenated portion, followed by the substrate-saturated Tris. The full cuvette was promptly sealed, inverted several times, and held at 30° C. for 2 min prior to NADPH addition to 1 AU.

In all turnovers, absorbance decay at 340 nm was monitored and the NADPH consumption rate was derived using ε₃₄₀=6.22 mM⁻¹ cm⁻¹. To ensure accurate coupling determination, enzyme concentrations of up to 2.5 μM were employed to drive the slower turnovers of WT and F87A to completion as necessary. Data from at least three experiments has been averaged to within ±5% (aromatics) or ±10% (alkalies and all turnovers with NADPH rates below 200 min⁻¹).

Product Analysis

For substrates other than lauric acid, 3 μL of internal standard (100 mM in DMSO) was added to 1000 μL of each completed turnover prior to extraction into 400 μL ethyl acetate or chloroform. Centrifugation was carried out at 21,000 g for 3½ min in 1500-μL microcentrifuge tubes. Products were identified by matching the GC elution times observed to those of authentic equivalents. FID responses were calibrated using a representative equivalent for each product group as detailed in the table below, using the assumption that isomeric mono-oxygenated products would give comparable responses. Samples containing a range of known concentrations of the chosen product and 1 mM in DMSO were prepared in Tris and extracted as above. The integrated peak areas derived were expressed as ratios of the internal standard peak areas and plotted against product concentration. 2-methyl-2-phenyl-propan-1-ol, which could not be sourced commercially, was produced in vivo, isolated and identified by MS: M149.00; and ¹H NMR: d 1.38 (6H, s, gem dimethyl), 3.59 (2H, s, CH₂), 7.24 (1H, m, p-phenyl), 7.34 (2H, m, m-phenyl), 7.37 (2H, m, o-phenyl). For lauric acid oxidation by CYP102A1 and its mutants, 990 μL of the incubation mixture was mixed with 10 μL of internal standard solution (25 mM decanoic acid in ethanol) and 2 μL of concentrated HCl. The mixture was extracted three times with 400 μL of ethyl acetate and the organic extracts were combined and dried over MgSO₄. Solvent was evaporated under a stream of dinitrogen and the sample dissolved in 200 μL acetonitrile. Excess (25 μL) N,O-Bis(trimethylsilyl)trifluoroacetamide with trimethylchlorosilane (BSTFA+TMCS, 99:1) was added and the mixture left for at least 120 min to produce the trimethylsilyl ester of the carboxylic acid group and trimethylsilyl ether of the alcohol, if formed. The reaction mixtures were used directly for GC analysis.

Calibrants, internal standards and oven temperatures used in GC product analysis. Internal Oven temperature, Substrate Calibrant Standard [Column length] Propylbenzene 1-phenyl-1-propanol Held at 60° C. for 1 min then raised n-butylbenzene 1-phenyl-2-butanol at 15° C. min⁻¹to 150° C. [7 m] Ethylbenzene 1-phenyl-1-ethanol Toluene o-cresol o-xylene 2-methylbenzylalcohol 4- m-xylene 2-methylbenzylalcohol benzylphenol t-butylbenzene 4-t-butylphenol p-cymene p-αα-trimethyl benzylalcohol cumene 2-phenyl-2-propanol R- & S- Perillyl alcohol limonenes fluorene 9-fluorenol 1,4- 2,5-dichlorophenol dichlorobenzene α-pinene α-pinene oxide β-ionone α-ionone epoxide Octane 2-octanol Held at 40° C. for 1 min then raised at 15° C. min⁻¹ to 130° C. [7 m] Naphthalene 1-naphthol Held at 100° C. for 1 min then raised Valencene nootkatone 1-undecanol at 15° C. min⁻¹ to 220° C. [7 m] Lauric acid 12-hydroxylauric acid decanoic acid Pentane 3-pentanol 2-octanol Raised from 70° C. to 90° C. at 1° C. min⁻¹ then raised at 65° C. min⁻¹ to 220° C. [60 m] 3-methylpentane 3-methyl-2-pentanol 2-methylbutane 3-methyl-2-butanol Butane 2-butanol 3-pentanol Raised from 60° C. to 80° C. at 2° C. min⁻¹ then raised at 70° C. min⁻¹ to Propane 2-propanol 220° C. [60 m]

Results

Of the variants generated by random mutagenesis which were screened both for enhanced activity and altered product selectivity in vivo, five specific variants were selected for in vitro studies. These were:

-   -   (i) A330P     -   (ii) A191T/N239H/I259V/A276T/L353I (Mutant KT2)     -   (iii) F87A/H171L/Q307H/N319Y (Mutant KSK19)     -   (iv) F87A/A330P/E377A/D425N (Mutant KT5)     -   (v) F87A/A117V/E131D/L215I (Mutant LO25)

All five mutants were readily expressed and purified by standard procedures (13). None showed evidence of formation of the inactive, “P420” form upon storage at −20° C. in 50% v/v glycerol for at least 15 months. Mutant LO25 has been less studied than the other four variants but it has the highest activity and selectivity of these five initial mutants for the damascone/ionone class of molecules, e.g. forming 86% of a hydroxydamascone product. The activities of A330P, KT2, KSK19, and KT5 were assayed with a wide range of substrates. The data for some of these are given in Tables 1 to 20 where the NADPH oxidation and product formation rates (PFR) are given in units of nmol (nmol P450)⁻¹ min⁻¹ and abbreviated to min⁻¹ henceforth in the text. The coupling efficiency is the yield of product based on the NADPH consumed and is given as a percentage. In some cases the catalytic parameters are compared to the A74G/F87V/L188Q (GVQ) mutant disclosed in NO20020380.

Four variants of the invention (A330P, KT2, KT5, KSK19) enhanced the PFR of WT with naphthalene (3.1 min⁻¹) by at least an order of magnitude, A330P being the most effective at 155 min⁻¹, though none could match the 487 min⁻¹ recorded by the GVQ variant (Table 1). In all cases 1-naphthol was the only GC-detectible product (23).

WT was considerably more active towards propylbenzene at 606 min⁻¹, with 70% coupling. Three of the four variants of the invention have a similar PFR to that of the GVQ variant (943 min⁻¹), while the fourth, KT2 significantly exceeded it at 2205 min⁻¹ (Table 2). WT and KT2 yielded ≧99% 1-phenyl-1-propanol, but the other new variants directed oxidation away from the activated benzylic position. Variant A330P gave 30% of the ortho-phenol, a product type not previously reported in CYP102A1 turnovers, while variant KT5, in which mutations F87A and A330P occur in combination, gave 80% 1-phenyl-2-propanol. Mutation F87A is known to promote 1-phenyl-2-propanol formation, but yields only 54% when acting alone (46).

The R47L/Y51F (RLYF) couplet, which had been shown to increase CYP102A1 activity for several substrates (13,14,17), was incorporated into variants A330P and KT2, with the aim of further raising product formation rates. Two highly active second generation variants resulted, RLYF/KT2 and RLYF/A330P. Single-site mutations were also introduced at various residues around the haem surface as well as the active site, and these were also combined with the 5 mutants identified in the first round. The activity of these second generation mutants were screened by the indigo formation and in vivo oxidation screening procedure. The I401P and Q403P mutants were identified as promising new variants from the in vivo oxidation procedure and they were prepared. The combination variants R47L/Y51F/I401P, F87A/I401P and R47L/Y51F/A330P/I401P were also prepared.

RLYF/KT2 matched the PFR of the GVQ variant in naphthalene turnovers at 496 min⁻¹, RLYF/A330P, at 666 min⁻¹, exceeded it by some 35% while I401P was still more active, at 1183 min⁻¹. Q403P showed a PFR of 121 min⁻¹ and 25% coupling, which were similar to the values for the variant KT2. The PFR of RLYF/KT2 with propylbenzene was 2688 min⁻¹, a 22% improvement over KT2. This rate approaches those reported for WT with natural substrates (47) while I401P at 3578 min⁻¹ exceeded the rates for natural substrates. Product profiles were little altered relative to the first generation variants, though RLYF/A330P gave some p-propylphenol (Table 2). KT2 was also combined with mutation F87A in order to make F87A-directed product profiles available at higher rates. Variant F87A/KT2 oxidized propylbenzene to 1-phenyl-1-propanol and 1-phenyl-2-propanol in roughly equal quantities, in line with mutant F87A, but at a PFR of 566 min⁻¹ versus 241 min⁻¹ for F87A.

Other alkylbenzenes were also examined as substrates for WT CYP102A1 and the new variants. Dramatic activity enhancements were observed with toluene (Table 3), in particular with RLYF/KT2, RLYF/A330P and I401P. The effect of the Q403P mutant was again similar to that of variant KT2. Large selectivity shifts were also evident, albeit for variants with lower product formation rates than the fastest mutants. WT CYP102A1 oxidized toluene predominantly to o-cresol (98%). This ring oxidation was unexpected since the benzylic C—H bonds are highly activated. For instance, WT CYP101A1 from Pseudomonas putida attacked the benzylic position to form >95% benzyl alcohol. Variant RLYF/A330P increased the PFR by a factor of 60 to 189 min⁻¹, coupling efficiency rising from 9% to 52% while keeping side-chain oxidation at a minimum. Addition of the I401P mutation gave rise to another increase in activity, with the NADPH and substrate oxidation rates rising to 3732 min⁻¹ and 1824 min⁻¹, respectively. Notably the coupling efficiency of 49% was largely unchanged from that of the RLYF/A330P (52%) and indeed the A330P (45%) variant, indicating that the main effect of the I401P mutation is enhanced NADPH turnover rate. Other variants showed both increased turnover activity and altered selectivity, e.g. variant F87A/KT2 gave 48% benzyl alcohol while variant KT5 yielded 95% benzyl alcohol and just 5% o-cresol (Table 3).

NADPH rates and coupling were generally lower with butylbenzene than propylbenzene, PFRs of 229 min⁻¹ and 1670 min⁻¹ being recorded for WT and the fastest variant, RLYF/KT2 (Table 4). Hydroxylation was no longer exclusively benzylic even within the WT-RLYF/KT2 sub-group, ˜10% taking place at each of the next two positions of the side-chain. Most other specificity changes mirrored those observed with propylbenzene. F87A variants increased oxidation at the non-benzylic positions—to as much as 80% with KT5—while variant F87L/KT2 formed substantial quantities of o-butylphenol (32%). However, A330P favored p-butylphenol formation, particularly when in combination with RLYF (26%), while cutting benzylic oxidation levels to just 10-13%.

With t-butylbenzene the NADPH turnover rates were in line with those for butylbenzene for most variants, but coupling levels were much reduced except in the case of F87A variants,_(Table 5). The GVQ variant, F87A/KT2 and KSK19 all improved PFRs by two orders of magnitude relative to WT, the highest rate being given by the new variant F87A/KT2 at 234 min⁻¹ versus 2.4 min⁻¹ for WT. F87A and F87V variants hydroxylated exclusively at the non-activated C—H bonds of the side chain to yield 2-methyl-2-phenyl-1-propanol, a compound that is awkward to synthesize by conventional methods. The majority of the products formed by WT and other variants were phenolic, with para-hydroxylation preferred over ortho-hydroxylation but again the A330P mutation increased the propensity for aromatic oxidation, shifting the product further to the para-phenol.

With ethylbenzene (Table 6) the variants of the invention generally showed enhanced activity over the WT (60 min⁻¹). RLYF/KT2, the fastest variant, gave a PFR of 1098 min⁻¹. RLYF/A330P also gave a high PFR (1062 min⁻¹), partly because A330P variants coupled better with ethylbenzene than WT (55-62% versus 28%). The coupling rates of Phe87 variants, by contrast, remained lower than those of WT (22-30%). WT again showed lower specificity for the benzylic position than in propylbenzene turnovers, forming 10% o-ethylphenol. A330P-containing mutants formed higher percentages of this product (21-27%), while F87A and F87V variants such as KSK19 and GVQ eliminated it from the product mix and yielded 100% 1-phenylethanol. KT5 turnovers produced small quantities of two other products: 2-phenylethanol and styrene. The former arises from oxidation at the non-activated, primary C—H bonds of the ethyl substituent while the latter represents the first observation to the Inventors' knowledge of dehydrogenation of a simple hydrocarbon catalyzed by CYP102A1.

Preferential attack at a methyl group next to an activated benzylic carbon is difficult to achieve because if these two types of bonds are at the same distance from and equally accessible to the P450 ferryl intermediate then the more activated C—H bond is attacked more rapidly. Hence KT5 may bind ethylbenzene in an orientation that places the methyl C—H bonds closer to the ferryl than the benzylic C—H bonds. In the dehydrogenation reaction the ferryl intermediate abstracts a hydrogen atom to form the Fe^(IV)—OH intermediate and the substrate radical then, instead of collapsing by recombining with the hydroxyl radical from the Fe^(IV)—OH moiety, abstracts a second hydrogen atom from the substrate to form the alkene and water. Dehydrogenation of 3-methylindole by a mammalian P450 enzyme was first reported in 1996 and this has since been extended to dehydrogenation by human P450 enzymes of indoline, capsaicin, and drugs (48-52). Aromatization of nifedipine via dehydrogenation by CYP102A1 has been reported (53). However, this reaction is driven by the formation of two delocalized aromatic systems.

The naturally occurring hydrocarbon, p-cymene (4-isopropyltoluene), is an interesting substrate as it is a precursor to four flavouring compounds. WT gave 82% p-α,α-trimethylbenzylalcohol, which arises from oxidation of the methine C—H bond of the isopropyl side-chain. Small quantities of the two possible aromatic hydroxylation products, thymol (3%) and carvacrol (7%) were also formed, and just 2% 4-isopropylbenzylalcohol. By contrast, variant A330P gave 19% thymol, 17% carvacrol, 22% 4-isopropylbenzylalcohol, and only 37% p-α,α-trimethylbenzylalcohol (Table 7). F87L/KT2 gave 74% 4-isopropylbenzylalcohol and 21% carvacrol, with the usual majority product, p-α,α-trimethylbenzylalcohol accounting for just 5% of the product mix. Activity enhancements were observed, with variant KSK19 giving a PFR of 1442 min⁻¹ versus 168 min⁻¹ for WT. p-α-Dimethylstyrene was formed via dehydrogenation of the isopropyl ring substituent. Moreover, once formed, this compound is also a substrate for the enzyme, and small quantities (1-3% of the total products) of the corresponding styrene oxide were observed. F87A- and F87V-containing variants minimized or eliminated phenol formation but gave significant quantities (>20%) of p-α-dimethylstyrene.

The variants of the invention showed increased cumene oxidation activity. The single-site mutants A330P and Q403P, and the KSK19 variant showed similar enhanced activity over the wild type, primarily due to increased NADPH turnover rates that were also higher than for the KT5 variant. The WT formed mostly the benzylic oxidation product while KT5 gave 27% 1-methylstyrene from dehydrogenation and also 1% of the styrene oxide product from further oxidation (Table 8a). The results show that an aromatic compound with a primary C—H bond in the 2-position of an alkyl substituent can give rise to dehydrogenation. This reaction pathway can form the basis of a method for synthesizing substituted styrenes which are precursors to polymers, e.g. preparation of vinylanisole from ethylanisole.

KT2 and A330P showed greatly enhanced activity towards short-chain alkanes compared to the wild type, particularly when in combination with RLYF (Tables 9-13). The I401P mutant also proved to be highly active. RLYF/KT2 and RLYF/A330P displayed similar product formation rates with pentane (1206 min⁻¹ and 1183 min⁻¹, based on coupling efficiencies of 60% and 67% respectively) that were 75 times those of the WT. The gain in coupling efficiency in these mutants is important since it shows greatly improved match between the active site topology and the substrate.

The high activities of these variants were maintained through 3-methylpentane (all >1000 min⁻¹ vs. ˜20 min⁻¹ for the WT, Table 10), 2-methylbutane (both RLYF/KT2 and RLYF/A330P>1000 min⁻¹ with I401P less active at 721 min⁻¹ vs. 51 min⁻¹ for WT, Table 11), and butane. The I401P mutation on its own mainly increased the NADPH turnover rate, and it combined well with the RLYF couplet, raising the PFR for 3-methylpentane oxidation to 2980 min⁻¹. On the other hand triple mutant RLYF/A330P displayed markedly better coupling than RLYF/KT2 with propane, forming 2-propanol at 46 min⁻¹ versus 5.8 min⁻¹. Addition of the I401P mutation increased the NADPH turnover rate, with a modest increase in coupling, leading to a PFR for propane oxidation of 430 min⁻¹ for the RLYF/A330P/I401P mutant. These rates compare to the 23 min⁻¹, 160 min⁻¹ and 370 min⁻¹ rates for previously reported CYP102A1 variants 9-10A, 1-12G and 53-5H, successive generations of alkane hydroxylases containing 13-15 mutations apiece (30,31). The GVQ variant used as a comparison gave a higher NADPH turnover rate than RLYF/A330P with propane (400 min⁻¹ versus 180 min⁻¹). As far as we are aware, its proficiency with this substrate has not been reported. However, coupling was only 0.7% versus 21% for RLYF/A330P. This is an extreme but characteristic example of how A330P and KT2 compare to GVQ across the range of substrates studied. Although NADPH rates of these two variants are often lower, overall product formation rates are generally higher on account of more efficient coupling. When this property is combined with the I401P mutation that mainly increased the turnover rate the resultant mutants, such as the R47L/Y51F/A330P/I401P, can achieve extraordinary activity increases over the wild type for a range of non-natural substrates.

Longer chain alkanes were poorer substrates for most mutants, RLYF/KT2 and RLYF/A330P giving PFRs of 246 min⁻¹ and 230 min⁻¹ with octane respectively, versus 53 min⁻¹ for WT (Table 13). Q403P showed a modest increase in activity of 2-fold over the wild type, to a PFR of 104 min⁻¹ while I401P was more active at 709 min⁻¹. RLYF/KT2 and I401P showed similar product selectivity to the wild type, but variant A330P significantly enhanced 2-octanol formation (53%, compared to 15% for WT, Table 13) at the expense of 3- and 4-octanol (31,54). This effect of directing oxidation of an alkane in the direction of the terminal positions is a useful asset for combining with other mutations in the overall search for terminal alcohol synthesis via direct alkane oxidation.

The variants of the invention also showed increased activity for oxidizing chlorinated aromatic compounds, as exemplified by 1,4-dichlorobenzene (1,4-DCB). The increases were mainly due to higher NADPH turnover activity while the couplings were not much higher than the WT. The highest coupling was 15% with the A330P variant (Table 14). Only one product was detected by gas chromatography but under the conditions used it was not possible to determine whether this was 2,4- or 2,5-dichlorophenol. The results demonstrated the efficacy of the variants of the invention for chlorinated benzene and aromatic oxidation.

We had previously reported oxidation of the sesquiterpene valencene by WT CYP102A1 and mutants such as F87A (14). The enzymes formed numerous products, including nootkatols, nootkatone and epoxidation products. The F87A mutation was shown to shift the product selectivity slightly towards nootkatone (˜20%). In comparison, variant KSK19 increases the oxidation rate of valencene 30-fold relative to the WT (Table 15). More crucially, it doubles the production rate of the grapefruit flavoring, nootkatone, relative to mutant F87A. Variants F87A/KT2 and KT5 increased the proportion of nootkatone to ˜30% while also raising the PFR over F87A on its own.

WO0031273 disclosed monoterpene oxidation by CYP102A1. The new variants showed higher activity than the WT and previously reported mutants. The catalytic properties of the new variants are compared with those of the WT for R- and S-limonene oxidation (Table 16; 16a). It is particularly notable that the two enantiomers formed different products with both enzymes but the turnover activities and couplings are closely similar, demonstrating the asymmetric nature of the CYP102A1 substrate pocket. Limonene oxidation activity was increased across all variants, with the Q403P, I401P and the R47L/Y51F/I401P triple mutant showing activities that were comparable or higher than that for the oxidation of a fatty acid natural substrate (lauric acid) by wild type CYP102A1 (1439 min⁻¹, see Table 20). Again these mutants showed similar product selectivity to the wild type, forming mainly the carveols, while the A330P- and F87A-containing mutations had altered selectivity, with the isopiperitenols being the major products. It is also clear that both KT2 and I401P functioned well as generic accelerator mutations. With (+)-α-pinene, the WT possessed little activity while the F87A/KT2 variant had a PFR of 206 min⁻¹ and shifted the product selectivity towards verbenol (Table 17). The effect of introducing the F87G mutation will be of interest. The I401P and F87A/I401P mutants were more active while maintaining the verbenols as the major products. Combination of I401P with the R47L/Y51F couplet raised the PFR to 1146 min⁻¹ but shifted the product to 56.5% of the cis-1,2-oxide, a selectivity trend that was further reinforced by the A330P mutation.

Fluorene is a more sterically demanding substrate than naphthalene, that was used in the in vivo screening procedure. The R47L/Y51F combination raised the activity slightly, and adding the A330P mutation increased the NADPH turnover rate to 510 min⁻¹ but the coupling efficiency was low (Table 18). The Q403P and I401P mutations had more significant effects, and the R47L/Y51F/I401P combination was particularly active, with a PFR of 582 min⁻¹ compared to 0.1 min⁻¹ for the wild type. The ionone class of compounds are precursors to flavouring compounds. Table 19 shows the β-ionone oxidation activity of wild type and some of the new variants, highlighting the activity increases possible with combination variants such as the R47L/Y51F/I401P.

Lauric acid (dodecanoic acid) is a recognized natural substrate of CYP102A1, with a NADPH turnover rate of 2777 min⁻¹ and PFR of 1439 min⁻¹. The structural perturbations introduced by the A330P mutation virtually abolished lauric acid oxidation by CYP102A1, while the I401P mutation enhanced the NADPH turnover rate while maintaining the coupling efficiency, leading to a mutant that is 40% more active than the wild type for the oxidation of a natural substrate. Clearly the rate of the first electron transfer is increased, suggesting a change in redox potential, haem spin state and reorganization energy for the process in this mutant. The R47L/Y51F/I401P mutant showed an even higher NADPH turnover rate but the coupling was lowered, presumably because the R47 and Y51 side chains were not available for carboxylate anchoring, altering the binding and hence coupling. The F87A mutation is known to shift lauric acid oxidation towards sub-terminal carbons, and the I401P mutation increased the activity while maintaining the selectivity altering effect of the F87A mutation.

These findings show that, despite the significant body of prior art, the CYP102A1 system remains fertile ground for the application of directed evolution and site-directed mutagenesis techniques, and that variants with improved activity and product selectivity can be characterised. All of the variants of the invention contain a number of mutations that to the Inventors' knowledge have not been disclosed previously.

The A330P mutation has the sought-after effect of increasing the activity towards a wide range of compounds while also altering the product profile when acting on its own as well as when combined with another selectivity-altering mutation (F87A). On the other hand, I401P functions as a generic rate accelerator with little effect on selectivity. I401 is on a β-bulge close to the haem and may affect electron transfer. A330P is an unlikely directed evolution product, relying for its potency on a solitary substitution derived from a single point mutation rather than a concert party of altered residues, as is common. Proline is introduced directly beside an existing proline at position 329, a substrate contact residue at the end of a β-strand. The resulting loss of backbone flexibility was predicted, and appears from the crystal structure (FIG. 2) to constrict the active site pocket, allowing tighter substrate binding and enhancing activity. This explanation is consistent with the unusual and potentially useful selectivity effects observed, which are typically the converse of those brought about by F87A, where the active site pocket is more open than in WT. It will be interesting to see whether the tactic of juxtaposing proline residues can usefully be deployed elsewhere in CYP102A1, or indeed in the redesign of other enzyme systems.

The crystal structure of the A330P mutant was obtained, and is shown in FIG. 2. The Calpha positions of this mutant were largely superimposable on those of the wild type, but there was significant rearrangement at positions 328, 329 and 330. As shown in FIG. 2, the introduced A330P mutation induced a dramatic shift of the ring of Pro329 towards the substrate binding pocket, reducing the active site volume and constricting the substrate access channel in a critical region. These structural changes most likely led to the unusual effects observed with the A330P mutation, such as the enhanced binding of non-natural substrates and altered product selectivity, due to the protrusion of the Pro329 ring into the substrate pocket. However they did not cause abrupt termination of secondary structure elements such as a helix.

Based on these unexpected findings, the potential for restructuring loop regions by introducing bulky residues such as proline was investigated further. Specifically, proline substitutions were carried out in the Ala399-Gln403 loop, which provides the proximal haem ligand, Cys400. Arg398 is involved in electrostatic and hydrogen bonding interactions, and may be important in stabilising the protein fold, while residues beyond Gln403 are probably too far removed from the haem to have any effects. The mutations explored were therefore A399P, I401P, G402P and Q403P. As shown in the Examples section, both I401P and Q403P brought significant enhancements to enzymic activity.

Mutating residues 401 and 403 to proline may induce conformational changes in the proximal loop so as to alter the strength of the Fe—S bonding interaction, e.g. by altering the Fe—S distance. This could render the haem iron easier to reduce, the reorganisation energy barrier to electron transfer would be lowered, as would the ease with which the haem iron could move into the plane of the porphyrin ring during the catalytic cycle.

The reorganisation of loop regions in CYP102A1 via the incorporation of bulky residues such as proline is a distinct and specific structural mechanism that is common to the A330P, I401P and Q403P substitution mutants of the current Invention.

Variant KT5, in which A330P and F87A occur together, promotes selectivity changes characteristic of F87A rather than A330P. However the shifts involved can be more pronounced than those brought about by other F87A-containing variants (e.g. 95% benzyl alcohol from toluene versus 48% with F87A/KT2, 23% with F87A and 2% with WT), and often occur at enhanced product formation rates, creating a range of complementary possibilities. It will be interesting to see how A330P combines with other known selectivity-directing mutations such as A264G, A82L and A328V.

Variants KT2 (A191T/N239H/I259V/A276T/L353I) and F87A/KT2 give product profiles that closely resemble those of WT and variant F87A respectively. Similarly I401P accelerated the rate for a range of substrates with identical product outcomes as the wild type. Hence KT2 and I401P function as rate accelerators. Component mutations N239H and I259V in KT2 are previously reported (55). However, variant KSK19, which contains an incipient F87A, has the same selectivity pattern as F87A/KT2 and is slightly more active across a range of substrates despite containing only three other mutations, suggesting that the F87A-free derivative of KSK19 may prove more potent than KT2 as a rate accelerator when it is prepared.

Of the mutations that appear to be acting as rate accelerators in KT2 and KSK19 (H171L, A191T, N239H, I259V, A276T, Q307H, N319Y and L353I), Gln307 and Asn319 (FIG. 1) are close to the region thought to be the docking site for the reductase domain from which the haem domain receives electrons (56), and may be able to influence electron transfer kinetics. Leu353 lies next to a substrate access channel residue, Met354, while Ala191, which is situated on the outer lip of the access channel, is noticeably displaced when palmitate binds (57), and could play a role in substrate enticement and/or capture. The remaining four mutations (His171, Asn239, IIe259, Ala276) are on or close to the protein surface and the detail mechanisms by which they function remain to be elucidated. It is speculated that the effects of at least some of the mutations may be rationalized in terms of their context in the CYP102A1 structure. The turnover activity of P450 enzymes is rate-limited by the rate of the first electron transfer step that initiates the catalytic cycle. The rate of electron transfer reactions are commonly discussed in terms of Marcus theory, which states that the activation energy to electron transfer depends of the thermodynamic driving force (the free energy change of the reaction) and the reorganization energy (energy input required to distort the reactant state to resemble the product state). Substrate binding plays a major role by altering the electronic properties of the haem, in most cases the sixth ligand to the haem iron is displaced, thus making the reaction thermodynamically more favorable (higher driving force) and lowering the reorganization energy barrier (less distortion of the reactant state is needed) for electron transfer (58). If the active site structure is altered, e.g. by an active site substitution, binding of non-natural substrates could be enhanced, and faster substrate oxidation is observed.

Another mechanism for altering substrate binding (and hence the electronic properties of the haem) may be induction of changes in the secondary structure elements surrounding the substrate pocket. In P450 enzymes, the substrate pocket is usually defined by residues from the B and B′ helices, the BC loop, the F/G loop, the G helix and the I helix. Amino acid substitutions at residues far away from the substrate pocket can alter substrate binding by inducing changes in the positions of these secondary structure elements. His171 is at the beginning of the F helix and contacts the G helix at L215. N239 is in the H helix and this helix contacts the N-terminal end of the I helix. Substitutions at H171 and N239 will affect the positioning of the G and I helices, respectively and can alter substrate binding. IIe259 and Ala276 are both in the I helix. Although these residues do not contact the substrate, amino acid substitutions may affect the active site structure, for example by inducing structural changes in the intervening residue, I263, which is located in the active site, and has been shown to alter the activity of CYP102A1 in the Inventors' earlier work (13).

It is of particular interest to note that variant LO25 contains the L215I mutation which can affect the contact between the F and G helices at the H171/L215 close approach. Overall, whilst none of the mutations are in the active site, all of them are at residues that play some role in the packing/interactions between secondary structure elements. The tandem-proline arrangement introduced by the A330P is unique and shows very unexpected but highly beneficial effects.

The mutations disclosed in the present invention may be introduced to existing variants (e.g. those containing the L188Q, R47L, Y51F mutations) for process development but also as starting points for further evolution.

REFERENCES

-   1. Miura, Y., and Fulco, A. J. (1975) Biochim. Biophys. Acta 388,     305-317. -   2. Cryle, M. J., Espinoza, R. D., Smith, S. J., Matovic, N. J., and     De Voss, J. J. (2006) Chem Commun, 2353-2355. -   3. Ravichandran, K. G., Boddupalli, S. S., Hasemann, C. A.,     Peterson, J. A., and Deisenhofer, J. (1993) Science 261, 731-736. -   4. Li, H., and Poulos, T. L. (1997) Nature Struct. Biol. 4, 140-146. -   5. Munro, A. W., Leys, D. G., McLean, K. J., Marshall, K. R.,     Ost, T. W., Daff, S., Miles, C. S., Chapman, S. K., Lysek, D. A.,     Moser, C. C., Page, C. C., and Dutton, P. L. (2002) Trends Biochem.     Sci. 27, 250-257. -   6. Urlacher, V. B., Lutz-Wahl, S., and Schmid, R. D. (2004) Appl.     Microbiol. Biotechnol. 64, 317-325. -   7. Bell, S. G., Hoskins, N., Whitehouse, C. J. C., and Wong,     L.-L. (2007) Metal Ions Life Sci. 3, 437-476. -   8. Graham-Lorence, S., Truan, G., Peterson, J. A., Falck, J. R.,     Wei, S., Helvig, C., and Capdevila, J. H. (1997) J. Biol. Chem. 272,     1127-1135. -   9. Oliver, C. F., Modi, S., Sutcliffe, M. J., Primrose, W. U.,     Lian, L. Y., and Roberts, G. C. K. (1997) Biochemistry 36,     1567-1572. -   10. Noble, M. A., Miles, C. S., Chapman, S. K., Lysek, D. A.,     Mackay, A. C., Reid, G. A., Hanzlik, R. P., and Munro, A. W. (1999)     Biochem. J. 339, 371-379. -   11. Cowart, L. A., Falck, J. R., and Capdevila, J. H. (2001) Arch.     Biochem. Biophys. 387, 117-124. -   12. Oliver, C. F., Modi, S., Primrose, W. U., Lian, L. Y., and     Roberts, G. C. K. (1997) Biochem. J. 327, 537-544. -   13. Carmichael, A. B., and Wong, L. L. (2001) Eur. J. Biochem. 268,     3117-3125. -   14. Sowden, R. J., Yasmin, S., Rees, N. H., Bell, S. G., and     Wong, L. L. (2005) Org. Biomol. Chem. 3, 57-64. -   15. Lussenburg, B. M., Babel, L. C., Vermeulen, N. P., and     Commandeur, J. N. (2005) Anal Biochem 341, 148-155. -   16. Wong, T. S., Wu, N., Roccatano, D., Zacharias, M., and     Schwaneberg, U. (2005) J Biomol Screen 10, 246-252. -   17. Urlacher, V. B., Makhsumkhanov, A., and Schmid, R. D. (2006)     Appl. Microbiol. Biotechnol. 70, 53-59. -   18. van Vugt-Lussenburg, B. M., Damsten, M. C., Maasdijk, D. M.,     Vermeulen, N. P., and Commandeur, J. N. (2006) Biochem. Biophys.     Res. Commun. 346, 810-818. -   19. van Vugt-Lussenburg, B. M., Stjernschantz, E., Lastdrager, J.,     Oostenbrink, C., Vermeulen, N. P., and Commandeur, J. N. (2007) J.     Med. Chem. 50, 455-461. -   20. Maves, S. A., Yeom, H., McLean, M. A., and Sligar, S. G. (1997)     FEBS Lett. 414, 213-218. -   21. Li, Q. S., Schwaneberg, U., Fischer, P., and     Schmid, R. D. (2000) Chem. Eur. J. 6, 1531-1536. -   22. Appel, D., Lutz-Wahl, S., Fischer, P., Schwaneberg, U., and     Schmid, R. D. (2001) J. Biotechnol. 88, 167-171. -   23. Li, Q. S., Ogawa, J., Schmid, R. D., and Shimizu, S. (2001)     Appl. Environ. Microbiol. 67, 5735-5739. -   24. Schulze, H., Schmid, R. D., and Bachmann, T. T. (2004) Anal.     Chem. 76, 1720-1725. -   25. Sulistyaningdyah, W. T., Ogawa, J., Li, Q. S., Maeda, C., Yano,     Y., Schmid, R. D., and Shimizu, S. (2005) Appl. Microbiol.     Biotechnol. 67, 556-562. -   26. Schwaneberg, U., Schmidt-Dannert, C., Schmitt, J., and     Schmid, R. D. (1999) Anal. Biochem. 269, 359-366. -   27. Li, Q. S., Schwaneberg, U., Fischer, M., Schmitt, J., Pleiss,     J., Lutz-Wahl, S., and Schmid, R. D. (2001) Biochim. Biophys. Acta     1545, 114-121. -   28. Farinas, E. T., Bulter, T., and Arnold, F. H. (2001) Curr. Opin.     Biotechnol. 12, 545-551. -   29. Glieder, A., Farinas, E. T., and Arnold, F. H. (2002) Nat.     Biotechnol. 20, 1135-1139. -   30. Meinhold, P., Peters, M. W., Chen, M. M., Takahashi, K., and     Arnold, F. H. (2005) Chem Bio Chem 6, 1-4. -   31. Peters, M. W., Meinhold, P., Glieder, A., and     Arnold, F. H. (2003) J. Am. Chem. Soc. 125, 13442-13450. -   32. Kubo, T., Peters, M. W., Meinhold, P., and Arnold, F. H. (2006)     Chemistry 12, 1216-1220. -   33. Munzer, D. F., Meinhold, P., Peters, M. W., Feichtenhofer, S.,     Griengl, H., Arnold, F. H., Glieder, A., and de Raadt, A. (2005)     Chem. Commun., 2597-2599. -   34. Lentz, O., Feenstra, A., Habicher, T., Hauer, B., Schmid, R. D.,     and B., U. V. (2005) Chem Bio Chem 7, 345-350. -   35. Ortiz de Montellano, P. R. (1986) Cytochrome P450: Structure,     Mechanism, and Biochemistry, Plenum Press, New York. -   36. Ortiz de Montellano, P. R. (ed) (1995) Cytochrome P450:     Structure, Mechanism, and Biochemistry, 2^(nd) Ed., Plenum Press,     New York. -   37. Ortiz de Montellano, P. R. (ed) (2005) Cytochrome P450:     Structure, Mechanism, and Biochemistry 3rd Ed., Kluwer     Academic/Plenum Press, New York. -   38. Poulos, T. L., Finzel, B. C., and Howard, A. J. (1987) J. Mol.     Biol. 195, 687-700. -   39. Poulos, T. L. (2005) Biochem. Biophys. Res. Commun. 338,     337-345. -   40. Poulos, T. L. (2005) Drug Metab Dispos 33, 10-18. -   41. Poulos, T. L. (2003) Proc. Natl. Acad. Sci. USA 100,     13121-13122. -   42. Poulos, T. L. (2003) Biochem. Biophys. Res. Commun. 312, 35-39. -   43. Hasemann, C. A., Kurumbail, R. G., Boddupalli, S. S.,     Peterson, J. A., and Deisenhofer, J. (1995) Structure 2, 41-62. -   44. Rupasinghe, S., Schuler, M. A., Kagawa, N., Yuan, H., Lei, L.,     Zhao, B., Kelly, S. L., Waterman, M. R., and Lamb, D. C. (2006) FEBS     Lett. 580, 6338-6342. -   45. Lepesheva, G. I., and Waterman, M. R. (2007) Biochim. Biophys.     Acta 1770, 467-747. -   46. Li, Q. S., Ogawa, J., Schmid, R. D., and Shimizu, S. (2001) FEBS     Lett. 508, 249-252. -   47. Capdevila, J. H., Wei, S., Helvig, C., Falck, J. R.,     Belosludtsev, Y., Truan, G., Graham-Lorence, S. E., and     Peterson, J. A. (1996) J. Biol. Chem. 271, 22663-22671. -   48. Sidles, G. L., and Yost, G. S. (1996) Chem. Res. Toxicol. 9,     291-297. -   49. Lanza, D. L., and Yost, G. S. (2001) Drug Metab Dispos 29,     950-953. -   50. Reilly, C. A., Ehlhardt, W. J., Jackson, D. A., Kulanthaivel,     P., Mutlib, A. E., Espina, R. J., Moody, D. E., Crouch, D. J., and     Yost, G. S. (2003) Chem. Res. Toxicol. 16, 336-349. -   51. Kassahun, K., Skordos, K., McIntosh, I., Slaughter, D., Doss, G.     A., Baillie, T. A., and Yost, G. S. (2005) Chem. Res. Toxicol. 18,     1427-1437. -   52. Sun, H., Ehlhardt, W. J., Kulanthaivel, P., Lanza, D. L.,     Reilly, C. A., and Yost, G. S. (2007) J Pharmacol Exp Ther 322,     843-851. -   53. Di Nardo, G., Fantuzzi, A., Sideri, A., Panicco, P., Sassone,     C., Giunta, C., and Gilardi, G. (2007) J Biol Inorg Chem 12,     313-323. -   54. Lentz, O., Feenstra, A., Habicher, T., Hauer, B., Schmid, R. D.,     and Urlacher, V. B. (2006) Chem Bio Chem 7, 345-350. -   55. Cirino, P. C., and Arnold, F. H. (2003) Angew. Chem. Int. Ed.     42, 3299-3301. -   56. Sevrioukova, I. F., Hazzard, J. T., Tollin, G., and     Poulos, T. L. (1999) J. Biol. Chem. 274, 36097-36106. -   57. Paulsen, M. D., and Ornstein, R. L. (1995) Proteins: Struct.,     Funct., Genet. 21, 237-243. -   58. Honeychurch, M. J., Hill, H. A. O., and Wong, L. L. (1999) FEBS     Lett. 451, 351-353.

TABLE A Sequence similarities between CYP102A1 haem domain (amino acid residues 1-470) and various structurally characterized cytochrome P450 enzymes. CYP102A1 Cytochrome P450 Identities Positives Gaps CYP505 188/452 (41%)  268/452 (59%)  10/452 (2%)  (P450foxy)* CYP3A4 114/395 (28%)  184/395 (45%)  37/395 (9%)  CYP51 100/410 (24%)  180/410 (43%)  27/410 (6%)  (M. tuberculosis) P4502R1 76/252 (30%) 126/252 (50%)  19/252 (7%)  CYP175A1 98/364 (26%) 150/364 (41%)  61/364 (16%) CYP2D6 59/232 (25%) 96/232 (41%) 24/232 (10%) CYP2A6 99/434 (22%) 174/434 (40%)  26/434 (5%)  CYP108A1 58/219 (26%) 97/219 (44%) 30/219 (13%) (P450terp) CYP2A13 99/437 (22%) 170/437 (38%)  26/437 (5%)  CYP2C8 57/198 (28%) 85/198 (42%) 7/198 (3%) CYP107L1  6/236 (27%) 102/236 (43%)  52/236 (22%) (P450pikC) CYP2B4 55/229 (24%) 102/229 (44%)  13/229 (5%)  CYP2C9 51/177 (28%) 80/177 (45%) 6/177 (3%) CYP2C5 49/165 (29%) 76/165 (46%) 6/165 (3%) CYP165B3 75/324 (23%) 127/324 (39%)  63/324 (19%) (P450oxyB) CYP154C1 59/216 (27%) 84/216 (38%) 38/216 (17%) CYP154A1 70/343 (20%) 138/343 (40%)  53/343 (15%) CYP245A1 47/179 (26%) 74/179 (41%) 34/179 (18%) CYP119A1 51/180 (28%) 80/180 (44%) 45/180 (25%) CYP8A1 46/157 (29%) 72/157 (45%) 24/157 (15%) CYP167A1 51/219 (23%) 94/219 (42%) 38/219 (17%) (P450epoK) CYP107A1 65/283 (22%) 114/283 (40%)  36/283 (12%) (P450eryF) CYP199A2 43/176 (24%) 73/176 (41%) 27/176 (15%) CYP101A1 56/223 (25%) 90/223 (40%) 57/223 (25%) (P450cam) CYP165C1 48/204 (23%) 90/204 (44%) 41/204 (20%) (P450oxyC) CYP119A2 44/166 (26%) 70/166 (42%) 35/166 (21%) CYP152A1 41/148 (27%) 62/148 (41%) 20/148 (13%) (P450BSβ) CYP121 44/184 (23%) 72/184 (39%) 35/184 (19%) *CYP505 (P450foxy) is not structurally characterized and the alignment used the haem domain only.

TABLE B Sequence similarities between CYP102A1 whole sequence and various cytochrome P450 enzymes (alignment done against proteins in the Swissprot protein databank). CYP102A1 Cytochrome P450 Identities Positives Gaps CYP102A2 627/1055 (59%) 781/1055 (74%) 12/1055 (1%) CYP102A3 614/1050 (58%) 785/1050 (74%)  9/1050 (1%) CYP505 395/1072 (36%) 586/1072 (54%) 43/1072 (4%) Note that, despite being in the same subfamily, CYP102A2 and CYP102A3 are only 59% and 58% homologous to CYP102A1.

TABLE C Physical characteristics of amino acids NON-AROMATIC Non-polar G A P I L V Polar - uncharged C S T M N Q Polar - charged D E H K R AROMATIC H F W Y

TABLE D Hydropathy scale Side Chain Hydropathy Ile 4.5 Val 4.2 Leu 3.8 Phe 2.8 Cys 2.5 Met 1.9 Ala 1.8 Gly −0.4 Thr −0.7 Ser −0.8 Trp −0.9 Tyr −1.3 Pro −1.6 His −3.2 Glu −3.5 Gln −3.5 Asp −3.5 Asn −3.5 Lys −3.9 Arg −4.5

TABLE 1 In vitro oxidation activity, coupling efficiency and selectivity of CYP102A1 variants with naphthalene. NADPH Coupling Product turnover efficiency formation % Variant rate (%) rate 1-ol WT and accelerator variants Wild-type 80 3.9 3.1 100 RLYF 166 19 32 100 KT2 490 23 113 100 I401P (IP) (1) 2816 42 1183 100 1401P (IP) (2) 2791 32 896 100 Q403P 484 25 121 100 RLYF/IP 4456 44 1939 100 RLYF/KT2 1306 38 496 100 F87A variants (KT5 also contains A330P) F87A 106 5.2 5.5 100 F87A/KT2 370 8.7 32 100 F87A/EP 1865 12 220 100 KSK19 511 11 56 100 KT5 567 5.5 31 100 F87V and F87L variants GVQ 2116 23 487 100 F87L/KT2 723 28 202 100 A330P variants A330P 483 32 155 100 RLYF/A330P(1) 1306 51 666 100 RLYF/A330P(2) 1333 51 680 100 RLYF/A330P/IP 1728 39 666 100 Rates are given in nmol · min⁻¹ · (nmol P450)⁻¹. The only detectable product was 1-naphthol (1-ol).

TABLE 2 In vitro oxidation activity, selectivity and spin shifts of CYP102A1 variants with propylbenzene. NADPH Coupling Product turnover efficiency formation % 1- % 2- % % Variant rate (%) rate ol ol ortho para WT and accelerator variants Wild-type (1) 866 70 606 99 — 1 — Wild-type (2) 894 71 635 99 1 — R47L/Y51F 2157 78 1682 99 1 — — KT2 2756 80 2205 99 — 1 — I401P (1) 4953 78 3863 98 1 1 — I401P (2) (*) 4476 80 3578 98 0.5 0.5 — RLYF/IP (*) 5550 91 5074 98.5 0.5 0.5 RLYF/KT2 3126 86 2688 100 — — — F87A variants (KT5 also contains A330P) F87A 670 36 241 47 53 — — F87A/KT2 1664 34 566 54 46 — — F87A/IP (*) 2176 41 897 61 38.5 — — KSK19 2079 51 1060 53 47 — — KT5 (*) 1062 65 690 20 79 — — F87V and F87L variant GVQ 3172 32 1015 78 14 8 — F87L/KT2 (*) 462 34 157 49 2 45 1 A330P variants A330P 1810 39 706 68 2 30 — RLYF/A330P (1) 2497 27 674 65 5 23 7 RLYF/A330P (2) 2524 27 681 65 5 23 7 RLYF/A330P/IP (*) 2592 28 721 75.5 2 20 1.5 Rates are given in nmol · min⁻¹ · (nmol P450)⁻¹. Products were 1-phenyl-1-propanol (1-ol), 1-phenyl-2-propanol (2-ol), 2-propylphenol (ortho) and 4-propylphenol (para). Small quantities of 1-phenyl-1-propanone (≦1%) and 3-phenyl-1-propanol (<0.5%, KT5 only) were also formed. — Not detected. (*) Percentages do not sum to 100 due to these and other minority products.

TABLE 3 In vitro oxidation activity and selectivity of CYP102A1 variants with toluene. NADPH Coupling Product turnover efficiency formation % % % % Variant rate (%) rate 1-ol ortho para others WT and accelerator variants Wild-type (1) 29 9.4 2.7 2 98 — — Wild-type (2) 57 3.9 2.2 2.5 96.5 1 — RLYF 57 13 7.4 1 98 1 — KT2 156 23 36 3 96 1 — I401P (1) 1248 25 312 3 96 — 1 I401P (2) 1326 14 180 — 100 — — Q403P 126 10 13 — 100 — — RLYF/IP 2539 16 415 — 99 — 1 RLYF/KT2 368 37 136 3 95 2 — F87A variants (KT5 also contains A330P) F87A 11 0.8 0.1 22 78 — — F87A/KT2 131 1.4 1.8 49 51 — — KSK19 115 2.1 2.4 43 57 — — KT5 217 2.9 6.3 95 5 — — F87V and F87L variants GVQ 1202 6.2 75 39 58 2 1 F87L/KT2 58 6.0 3.5 33 64 — 3 A330P variants A330P 189 45 85 1 98 1 — RLYF/A330P 363 52 189 1 97 1 1 RLYF/A330P/IP 3732 49 1824 — 100 — — Rates are given in nmol · min⁻¹ · (nmol P450)⁻¹. Products were benzylalcohol (1-ol), o-cresol (ortho) and p-cresol (para). — Not detected.

TABLE 4 In vitro oxidation activity and selectivity of CYP102A1 variants with butylbenzene. NADPH Coupling Product turnover efficiency formation % % % % % % Variant rate (%) rate 1-ol (*) 2-ol 3-ol ortho para others WT and accelerator variants Wild-type 457 64 292 80 10 8 2 — — RLYF 996 69 687 80 10 9 1 — — KT2 2124 68 1444 80 10 8 2 — — RLYF/KT2 2299 73 1678 80 11 8 1 — — F87A variants (KT5 also contains A330P) F87A 795 49 390 43 46 10 — — 1 F87A/KT2 1357 43 584 49 42 9 — — — KSK19 1729 51 882 48 41 10 — — 1 KT5 1277 53 677 18 45 35 — — 2 F87V and F87L variants GVQ 3166 38 1203 49 28 15 7 — 1 F87L/KT2 420 16 67 41 10 5 32 1 11  A330P variants A330P 1617 25 404 14 37 19 10 20 — RLYF/A330P 2094 22 461 11 29 26 6 26 2 Rates are given in nmol · min⁻¹ · (nmol P450)⁻¹. Products were 1-phenyl-1-butanol (1-ol), 1-phenyl-2-butanol (2-ol), 4-phenyl-2-butanol (3-ol), 2-butylphenol (ortho) and 4-butylphenol (para). (*) includes 1-3% 1-phenyl-1-butanone. — Not detected.

TABLE 5a In vitro oxidation activity, selectivity and spin shifts of CYP102A1 variants with t-butylbenzene. Product NADPH Coupling formation % Variant turnover rate efficiency (%) rate ortho % para % 1-ol WT and accelerator variants Wild-type 304 0.8 2.4 14 63 23 R47L/Y51F 963 0.6 5.8 7 61 34 KT2 1429 1.0 14 10 70 20 RLYF/KT2 2808 0.4 11 — 41 59 F87A variants (KT5 also contains A330P) F87A 329 11 36 — — 100 F87A/KT2 1946 12 234 — — 100 KSK19 1548 13 201 — — 100 KT5 1297 16 208 — — 100 F87V and F87L variants GVQ 2753 4.3 118 — — 100 F87L/KT2 307 1.9 5.8 29 61 10 A330P variant A330P 1421 1.8 26 8 82 10 RLYF/A330P 1983 3.7 73 2 92 6 Rates are given in nmol · min⁻¹ · (nmol P450)⁻¹. Products were 2-t-butylphenol (ortho), 4-t-butylphenol (para) and 2-methyl-2-phenyl-propan-1-ol (1-ol). — Not detected.

TABLE 5b In vitro oxidation activity/selectivity and spin shifts of CYP102A1 variants with ethylbenzene. NADPH Coupling Product turnover efficiency formation % % % % Variant rate (%) rate 1-ol 2-ol ortho styrene WT and accelerator variants Wild-type (1) 123 49 60 90 — 10 — Wild-type (2) 123 28 34 90 10 R47L/Y51F 433 51 221 95 —  5 — KT2 806 53 427 91 —  9 — RLYF/KT2 1861 59 1098 93 —  7 — F87A variants (KT5 also contains A330P) F87A 138 22 30 100 — — — F87A/KT2 570 20 114 100 — — — KSK19 710 24 170 100 — — — KT5 488 31 151 93 4 — 3 F87V and F87L variants GVQ 2201 26 572 100 — — — F87L/KT2 169 19 32 79 — 21 — A330P variants A330P 720 55 396 73 — 27 — RLYF/A330P 1713 62 1062 74 — 26 — Rates are given in nmol · min⁻¹ · (nmol P450)⁻¹. Products were 1-phenylethanol (1-ol), 2-phenylethanol (2-ol), 2-ethylphenol (ortho) and styrene. — Not detected. NB/Results were also obtained for F87A, F87A/KT2, KSK19 and GVQ following recalibration of detector response. NADPH turnover was identical. Coupling efficiencies were 23 (F87A), 21 (F87A/KT2), 25 (KSK19), 26 (GVQ). Product formation rates were 32 (F87A), 120 (F87A/KT2), 178 (KSK19), 572 (GVQ). 1-ol was 99% (F87A), 96% (F87A/KT2), 95% (KSK19), 99% (GVQ). Styrene was now detected in reactions with these variants at 2% (F87A), 4% (F87A/KT2), 5% (KSK19), 1% (GVQ).

TABLE 6a In vitro oxidation activity and selectivity of CYP102 variants with o-xylene. NADPH Coupling Product % turnover efficiency formation 1- % 2,3 % 3,4 % % Variant rate (%) rate ol phenol phenol hydroquinone catechol WT and accelerator variants Wild-type 32 14 4.5 47 27 10 8 8 R47L/Y51F 77 36 28 49 24 10 9 8 KT2 291 43 125 57 22 8 7 6 RLYF/KT2 584 61 356 57 20 9 8 6 F87A variants (KT5 also contains A330P) F87A 133 11 15 94 1 — 2 3 F87A/KT2 197 14 28 92 1 — 2 5 KSK19 133 20 27 93 2 1 2 2 KT5 (*) 237 36 85 99 — — — — F87V and F87L variants GVQ (*) 1520 29 441 84 6 2 4 3 F87L/KT2 (*) 134 23 31 79 10 3 3 3 A330P variants A330P 307 49 150 28 29 14 16 13 RLYF/A330P 694 79 548 29 28 15 15 13 Rates are given in nmol · min⁻¹ · (nmol P450)⁻¹. Products were 2-methylbenzylalcohol (1-ol), 2,3-dimethylphenol (2,3-phenol), 3,4-dimethylphenol (3,4-phenol), 2,3-dimethyl-p-benzoquinone (hydroquinone) and pyrocatechol (catechol). (*) Percentages do not sum to 100 due to minority products. — Not detected.

TABLE 6b In vitro oxidation activity and selectivity of CYP102A1 variants with m- xylene. NADPH Coupling Product turnover efficiency formation % 2,4 Variant rate (%) rate % 1-ol phenol % 2,6 phenol WT and accelerator variants Wild-type 27 29 7.8 2 87 11 R47L/Y51F 143 38 54 2 90 8 KT2 545 40 218 4 86 10 RLYF/KT2 (*) 1152 50 576 3 87 8 F87A variants (KT5 also contains A330P) F87A 90 13 12 45 54 1 F87A/KT2 253 10 25 49 50 1 KSK19 367 12 44 47 51 2 KT5 369 15 55 83 16 1 F87V and F87L variants GVQ 1611 15 242 23 71 6 F87L/KT2 192 14 27 23 67 10 A330P variants A330P 429 48 206 1 85 14 RLYF/A330P 1282 64 820 1 87 12 Rates are given in nmol · min⁻¹ · (nmol P450)⁻¹. Products were 3-methylbenzylalcohol (1-ol), 2,4-dimethylphenol (2,4-phenol) and 2,6-dimethylphenol (2,6-phenol). (*) Percentages do not sum to 100 due to minority products.

TABLE 7 In vitro oxidation activity/selectivity and spin shifts of CYP102A1 variants with p-cymene. NADPH Coupling Product turnover efficiency formation % p-α- % i- % Me- % % % Variant rate (%) rate DMS(*) Pr-ol ol thymol carvacrol other WT and accelerator variants Wild-type 467 36 168  6 82 2 3 7 — R47L/Y51F 1648 41 676  4 88 1 2 5 — KT2 1867 44 821  5 80 3 4 8 — RLYF/KT2 2919 48 1401  7* 77 4 5 6 1 F87A variants (KT5 also contains A330P) F87A 413 38 157  8* 92 — — — — F87A/KT2 2234 51 1139 20* 78 2 — — — KSK19 2721 53 1442 23* 76 1 — — — KT5 1403 50 702 22* 76 2 — — — F87V and F87L variants GVQ (**) 2799 28 784 27* 71 1 — — — F87L/KT2 475 16 76 — 5 74 — 21  — A330P variants A330P 1040 26 270  4* 35 19 19  16  7 RLYF/A330P 1825 26 475  7* 42 28 12  8 3 Rates are given in nmol·min⁻¹·(nmol P450)⁻¹. Products were p-α-dimethylstyrene (p-α-DMS), p-α-α-trimethylbenzylalcohol (i-Pr-ol), 4-isopropylbenzylalcohol (Me-ol), thymol, carvacrol and an unidentified product. (*) includes up to 3% p-α-dimethylstyreneoxide. (**) Percentages do not sum to 100 due to other minority products. — Not detected.

TABLE 8 In vitro oxidation activity and selectivity of some CYP102A1 variants with cumene. NADPH Coupling Product turnover efficiency formation styrene 1- 2- Variant rate (%) rate styrene oxide ol ol ortho para Wildtype 419 31 130 2 — — 83 14 1 A330P 1687 32 540 9 2 1 71 15 2 Q403P 1621 38 616 12.5 — — 83 4.5 — KSK19 1755 37 649 23 6 1 70 — — KT5 755 39 294 31 4 3 62 — — Rates are given in nmol · min⁻¹ · (nmol P450)⁻¹. Products were α-methylstyrene (styrene), α-methylstyrene oxide (styrene oxide), 2-phenyl-1-propanol (1-ol), 2-phenyl-2-propanol (2-ol), 2-isopropylphenol (ortho) and 4-isopropylphenol (para). — Not detected.

TABLE 8a In vitro oxidation activity and selectivity of some CYP102A1 variants with cumene after further GC analysis. NADPH Coupling Product turnover efficiency formation styrene 1- 2- Variant rate (%) rate styrene oxide ol ol ortho para Wildtype 419 31 130 8.5 — — 81 10.5 — A330P 1687 31 523 7 — 1 75 15 2 Q403P 1621 38 616 12.5 — — 83 4.5 — KSK19 1755 34 597 19 1 1 79 — — KT5 755 37 279 27 1 3 69 — — Rates are given in nmol · min⁻¹ · (nmol P450)⁻¹. Products were α-methylstyrene (styrene), α-methylstyrene oxide (styrene oxide), 2-phenyl-1-propanol (1-ol), 2-phenyl-2-propanol (2-ol), 2-isopropylphenol (ortho) and 4-isopropylphenol (para). — Not detected.

TABLE 9 In vitro oxidation activity, selectivity and spin shifts of CYP102A1 variants with pentane. NADPH Coupling Product % % % turnover efficiency formation 2- 3- 2- % Variant rate (%) rate ol ol one 3-one WT and accelerator variants Wild-type 74 21 16 59 39 — 2 R47L/Y51F 361 45 162 58 42 — — KT2 1103 56 618 59 41 — — I401P 2325 42 977 57 38 2 3 RLYF/KT2 2010 60 1206 63 37 — — F87A variants F87A 155 18 28 62 38 — — F87A/KT2 538 22 118 57 43 — — KSK19 738 27 199 56 41 1 2 KT5 502 19 95 65 35 — — F87V variant GVQ 2107 28 590 47 52 — 1 A330P variants A330P 959 65 623 62 38 — — RLYF/ 1766 67 1183 63 37 — — A330P Rates are given in nmol · min⁻¹ · (nmol P450)⁻¹. Products were 2-pentanol (2-ol), 3-pentanol (3-ol), 2-pentanone (2-one) and 3-pentanone (3-one).

TABLE 10 In vitro oxidation activity/selectivity and spin shifts of CYP102A1 variants with 3-methylpentane. NADPH Coupling Product % % turnover efficiency formation 2-ol 2-ol % Variant rate (%) rate (A) (B) 3-ol WT and accelerator variants Wild-type 98 41 40 69 19 13 R47L/Y51F 568 58 329 65 22 13 KT2 1005 57 573 67 20 13 I401P (IP) (1) 2566 46 1180 66 19 15 I401P (IP) (2) 2763 50 1378 63 22 15 Q403P 685 52 356 65 19 16 RLYF/IP 4925 61 2980 58 26.5 15.5 RLYF/KT2 1713 60 1028 64 23 13 F87A variants (KT5 also contains A330P) F87A 184 27 50 15 9 76 F87A/KT2 530 37 196 14 9 77 F87A/IP 1569 36 565 15.5 11.5 73 KSK19 469 40 188 13 9 78 KT5 570 42 239 10 7 83 F87V variant GVQ 1856 32 594 36 17 47 A330P variants A330P 982 64 628 59 23 18 RLYF/A330P 1986 67 1331 54 27 19 RLYF/ 2277 68 1553 41.5 33 25.5 A330P/IP Rates are given in nmol · min⁻¹ · (nmol P450)⁻¹. Products were 3-methyl-2-pentanol (2-ol) - two diastereomers designated (A) and (B), and 3-methyl-3-pentanol (3-ol).

TABLE 11 In vitro oxidation activity and selectivity of CYP102A1 variants with 2-methylbutane. NADPH Coupling Product turnover efficiency formation % 1- % 2- % 3- % 4- % 3- Variant rate (%) rate ol ol ol ol one WT and accelerator variants Wild-type 118 43 51 2 21 77 — — R47L/Y51F 449 48 216 1 21 78 — — KT2 902 53 478 2 21 77 — — I401P 2120 34 721 1 20 79 — — RLYF/KT2 1782 62 1105 2 22 76 — — F87A variants (KT5 also contains A330P) F87A/KT2 712 24 171 1 82 17 — — KT5 453 28 127 1 83 15 — 1 F87V and F87L variants GVQ 1682 27 454 2 52 45 1 — F87L/KT2 88 6 5 5 24 71 — — A330P variant RLYF/A330P 2151 69 1484 2 31 67 — — Rates are given in nmol · min⁻¹ · (nmol P450)⁻¹. Products were 2-methyl-1-butanol (1-ol), 2-methyl-2-butanol (2-ol), 3-methyl-2-butanol (3-ol), 3-methyl-1-butanol (4-ol) and 3-methyl-2-butanone (3-one). — Not detected.

TABLE 12 In vitro oxidation activity and selectivity of some CYP102A1 variants with butane and propane. NADPH Coupling Product turnover efficiency formation % 1- % 2- % 2- Variant rate (%) rate ol ol one Butane Wild-type 55 19 10 — 99 1 GVQ 1377 15 207 — 98 2 RLYF/KT2 1123 52 584 — 97 3 RLYF/A330P 764 62 474 1   92 7 Propane Wild-type (1) 1 0.1 0.001 — 100 — Wild-type (2) 27 0.7 0.2 73   27 — GVQ 404 0.7 2.8 — 100 — RLYF/KT2 90 6.4 5.8 — 100 — RLYF/A330P 180 21 38 — 100 — (1) RLYF/A330P 220 21 46 — 100 — (2) I401P (IP) 684 3.7 25 — 100 — F87A/IP 727 1.3 9.6 — 100 — RLYF/IP 1245 8.5 106 — 100 — RLYF/A330P/ 1264 29 430 4.5 95.5 — IP Rates are given in nmol · min⁻¹ · (nmol P450)⁻¹. Products were 1-butanol (1-ol), 2-butanol (2-ol) and 2-butanone (2-one) for butane and 2-propanol only for propane.

TABLE 13 In vitro oxidation activity and selectivity of CYP102A1 variants with octane. NADPH Coupling Product turnover efficiency formation % 2- % 3- % 3- % 4- Variant rate (%) rate ol ol % 4-ol one one WT and accelerator variants Wild-type 148 36 53 15 43 42 — — RLYF/KT2 770 32 246 16 40 43 — 1 I401P 2215 32 709 14 44 42 — — Q403P 471 22 104 8 46 46 — — F87A variants (KT5 also contains A330P) F87A 181 28 51 10 38 43 7 2 F87A/KT2 628 27 170 11 37 43 7 2 KT5 519 17 83 12 35 25 24  4 A330P variants A330P 642 26 167 53 30 16 1 — RLYF/A330P 1046 22 230 56 25 17 2 — Rates are given in nmol · min⁻¹ · (nmol P450)⁻¹. Products were 2-octanol (2-ol), 3-octanol (3-ol), 4-octanol (4-ol), 3-octanone (3-one) and 4-octanone (4-one). — Not detected.

TABLE 14 In vitro oxidation activity and selectivity of some CYP102A1 variants with 1,4-dichlorobenzene. NADPH Coupling Product turnover efficiency formation % Variant rate (%) rate product WT and accelerator variants Wild-type 544 10  54 100 RLYF 1161 16 186 100 KT2 1685  8 135 100 RLYF/KT2 2603  7 182 100 F87A variants F87A 655 — — — F87A/KT2 1921 — — — KSK19 2549 — — — F87V variant GVQ 1988 — — — A330P variants A330P 1126 15 169 100 RLYF/A330P 2039 12 245 100 Rates are given in nmol · mm⁻¹ · (nmol P450)⁻¹. Products were 2,4-dichlorophenol and/or 2,5-dichlorophenol, which have identical GC elution times. Further oxidation to a GC-indetectible semiquinone may make the coupling figures unreliable.

TABLE 15 In vitro oxidation activity and selectivity of CYP102A1 variants with valencene. NADPH Coupling Product % % turnover efficiency formation % % Val. Noot. % Variant rate (%) rate Nootkatols Nootkatone epox. epox. others WT and accelerator variants Wild-type 42 16 6.7 21 — 34 6 39 R47L/Y51F 194 21 41 11 1 50 2 36 Q403P 277 14 39 25 — 52 1 22 KT2 339 17 58 7 1 54 9 29 RLYF/KT2 519 22 114 7 — 66 3 24 F87A variants (KT5 also contains A330P) F87A 443 24 106 36 23 21 5 15 F87A/KT2 671 24 161 24 32 20 11 13 KSK19 1050 21 221 24 25 23 11 17 KT5 557 23 128 18 30 30 14  8 F87V variant GVQ 540 17 92 29 11 36 8 16 A330P variant A330P 14 5.0 0.7 39 4 — 16 41 RLYF/A330P 61 11 6.7 43 — 10 2 45 Rates are given in nmol · min⁻¹ · (nmol P450)⁻¹. Products were cis- and trans-nootkatols (nootkatols), nootkatone, cis- and trans-valencene epoxides (Val. epox.) and cis- and trans-nootkatone epoxides (Noot. epox.).

TABLE 16 In vitro oxidation activity and selectivity of some CYP102A1 variants with R- and S-limonene. NADPH Coupling Product turnover efficiency formation Variant rate (%) rate epoxides 4.07 min Isopiper carveols others R-limonene Wild- 463 43 199 27 — 15 55 3 type F87A/ 1249 42 525 9 7 66 2 16 KT2 RLYF/ 1596 49 782 33 — 48 5 14 A330P RLYF/ 1986 54 1072 28 — 19 49 4 KT2 S-limonene Wild- 361 40 144 43 1 31 21 4 type F87A/ 1105 45 497 26 17  41 3 13 KT2 Rates are given in nmol · min⁻¹ · (nmol P450)⁻¹. Products were 1,2-limonene epoxides (epoxides), cis- and trans-isopiperitenol (isopiper), and cis- and trans-carveols (carveols).

TABLE 16a In vitro oxidation activity and selectivity of CYP102A1 variants with R- limonene. % % % % % % cis- tr- 6- 6- % % C cis- tr- 3- 3- ol ol 6- 10- % Variant N (%) PFR 1,2 1,2 % U ol ol (A) (B) one ol other Wild- 491 40 196 16.5 4.5 0.5 5.5 10.5 49 9.5 0.5 1 2.5 type (WT) F87A/ 1249 42 545 4 3 5.5 10 58 2 0.5 — 4 13 KT2 Q403P 2053 77 1581 20 4.5 0.5 5 11 40 10.5 4 0.5 4 I401P 3490 69 2403 18.5 4.5 0.5 4 13 42 10.5 2.5 1.5 3 (IP) F87A/ 1195 56 666 10 6.5 5.5 6.5 45.5 3 2 4.5 6.5 10 IP RLYF/ 4479 70 3123 20 4.5 0.5 4 11.5 42 10.5 2.5 1.5 3 IP RLYF/ 1345 61 825 22.5 11 0.5 6 33.5 6 3 3.5 5 9 A330P/ IP RLYF/ 1623 48 779 18.5 12.5 — 10 39 3 2.5 — 6 8.5 A330P N = NADPH turnover rate. C = coupling. PFR = product formation rate. Rates in nmol min⁻¹ (nmol P450)⁻¹. Products were cis-1,2-limonene epoxide (cis-1,2), trans-1,2-limonene epoxide (tr-1,2), unidentified product (U), cis-isopiperitenol (cis-3-ol), trans-isopiperitenol (tr-3-ol), carveol (2 isomers) (6-ol (A) and (B)), carvone (6-one) and perillyl alcohol (10-ol).

TABLE 17 In vitro oxidation activity and selectivity of some CYP102A1 variants with (+)-α-pinene. NADPH Coupling Product turnover efficiency formation Variant rate (%) rate Epoxides Verbenols Verbenones Myrtenol others Wild- <1 ~16 <0.2 31 44 7 5 13 type F87A/ 469 44 206 14 64 7 4 11 KT2 Rates are given in nmol · min⁻¹ · (nmol P450)⁻¹. Products were 2,3-pinene epoxides (epoxides), cis- and trans-verbenol (verbenols), verbenone, and myrtenol. Data overstates coupling due to impurities in substrate.

TABLE 17a In vitro oxidation activity and selectivity of some CYP102A1 variants with (+)-α-pinene. % % % % C (−)- (+)- cis-4- % tr- % 4- 10- % Variant N (%) PFR 2,3 2,3 ol 4-ol one ol other Wild-type (WT) 41 0 0 — — — — — — — I401P (IP) 1229 19 238 18 1 32 41.5 2 0.5 5 F87A/IP 1039 41 422 26.5 2 35 28 1.5 4.5 2.5 RLYF/IP 2770 41 1146 56.5 0.5 17.5 22.5 1.5 0.5 1 RLYF/A330P/IP 1294 29 373 78.5 — 9 5.5 4.5 0.5 2 RLYF/A330P 712 37 263 85 0.5 4 4.5 3.5 0.5 2 Rates are given in nmol · min⁻¹ · (nmol P450)⁻¹. N = NADPH turnover rate. C = coupling. PFR = product formation rate. Rates in nmol min⁻¹ (nmol P450)⁻¹. Products were (−)-2,3-pinene epoxide ((−)-2,3), (+)-2,3-pinene epoxide ((+)-2,3), cis-verbenol (cis-4-ol), trans-verbenol (tr-4-ol), verbenone (4-one) and myrtenol (10-ol).

TABLE 18 In vitro oxidation activity and selectivity of CYP102A1 variants with fluorene. Variant N C (%) PFR % 9-ol % 9-one Wild-type (WT) 7.9 0.9 0.1 71 29 I401P (IP) 1057 18 188 100 — Q403P 277 7 19 100 F87A/IP 871 7.8 68 100 — RLYF/IP 2283 26 582 100 — RLYF/A330P/IP 2473 4.6 114 100 — RLYF/A330P 510 3.6 18 100 — N = NADPH turnover rate. C = coupling. PFR = product formation rate. All rates in nmol min⁻¹ (nmol P450)⁻¹. Products were 9-fluorenol (9-ol) and 2-fluorenone (9-one).

TABLE 19 In vitro oxidation activity and selectivity of CYP102A1 variants with β-ionone. Variant N C (%) PFR % 4-ol % other Wild-type (WT) 241 34 82 100 — I401P (IP) 3262 58 1894 98 2 F87A/IP 1190 38 450 99.5 0.5 RLYF/IP 3078 63 1949 99 1 RLYF/A330P/IP 1462 54 789 100 — RLYF/A330P 727 51 373 100 — N = NADPH turnover rate. C = coupling. PFR = product formation rate. Rates are in nmol min⁻¹ (nmol P450)⁻¹. Products were 4-hydroxy-β-ionone (4-ol).

TABLE 20 In vitro oxidation activity and selectivity of CYP102A1 variants with lauric (dodecanoic) acid. C % Variant N (%) PFR % ω-1 % ω-2 % ω-3 % ω-4 % ω-5 other Wild-type (WT) 2777 52 1439 33.5 29 37 0.5 — — I401P (IP) 3812 53 2012 36 30.5 33 0.5 — — F87A/IP 1468 21 300 6 11 36.5 17.5 28.5 0.5 RLYF/IP 4410 44 1928 30.5 38.5 30 1 — — RLYF/A330P/IP 348 1.8 6.2 18 40 40 2 — — RLYF/A330P 47 0 0 — — — — — — N = NADPH turnover rate. C = coupling. PFR = product formation rate. Rates in nmol min⁻¹ (nmol P450)⁻¹. Products were 11-hydroxydodecanoic acid (ω-1), 10-hydroxydodecanoic acid (ω-2), 9-hydroxydodecanoic acid (ω-3), 8-hydroxydodecanoic acid (ω-4) and 7-hydroxydodecanoic acid (ω-5).

Sequence of the Invention (CYP102A1 Wild Type)

aca att aaa gaa atg cct cag cca aaa acg ttt gga gag ctt aaa   45 Thr Ile Lys Glu Met Pro Gln Pro Lys Thr Phe Gly Glu Leu Lys 1               5                   10                  15 aat tta ccg tta tta aac aca gat aaa ccg gtt caa gct ttg atg   90 Asn Leu Pro Leu Leu Asn Thr Asp Lys Pro Val Gln Ala Leu Met                 20                  25                  30 aaa att gcg gat gaa tta gga gaa atc ttt aaa ttc gag gcg cct  135 Lys Ile Ala Asp Glu Leu Gly Glu Ile Phe Lys Phe Glu Ala Pro                 35                  40                  45 ggt cgt gta acg cgc tac tta tca agt cag cgt cta att aaa gaa  180 Gly Arg Val Thr Arg Tyr Leu Ser Ser Gln Arg Leu Ile Lys Glu                 50                  55                  60 tgc gat gaa tca cgc ttt gat aaa aac tta agt caa gcg gca ctt  225 Ala Cys Asp Glu Ser Arg Phe Asp Lys Asn Leu Ser Gln Ala Leu                 65                  70                  75 aaa ttt gta cgt gat ttt gca gga gac ggg tta ttt aca agc tgg  270 Lys Phe Val Arg Asp Phe Ala Gly Asp Gly Leu Phe Thr Ser Trp                 80                  85                  90 acg cat gaa aaa aat tgg aaa aaa gcg cat aat atc tta ctt cca  315 Thr His Glu Lys Asn Trp Lys Lys Ala His Asn Ile Leu Leu Pro                 95                  100                 105 agc ttc agt cag cag gca atg aaa ggc tat cat gcg atg atg gtc  360 Ser Phe Ser Gln Gln Ala Met Lys Gly Tyr His Ala Met Met Val                 110                 115                 120 gat atc gcc gtg cag ctt gtt caa aag tgg gag cgt cta aat gca  405 Asp Ile Ala Val Gln Leu Val Gln Lys Trp Glu Arg Leu Asn Ala                 125                 130                 135 gat gag cat att gaa gta ccg gaa gac atg aca cgt tta acg ctt  450 Asp Glu His Ile Glu Val Pro Glu Asp Met Thr Arg Leu Thr Leu                 140                 145                 150 gat aca att ggt ctt tgc ggc ttt aac tat cgc ttt aac agc ttt  495 Asp Thr Ile Gly Leu Cys Gly Phe Asn Tyr Arg Phe Asn Per Phe                 155                 160                 165 tac cga gat cag cct cat cca ttt att aca agt atg gtc cgt gca  540 Tyr Arg Asp Gln Pro His Pro Phe Ile Thr Per Met Val Arg Ala                 170                 175                 180 ctg gat gaa gca atg aac aag ctg cag cga gca aat cca gac gac  585 Leu Asp Glu Ala Met Asn Lys Leu Gln Arg Ala Asn Pro Asp Asp                 185                 190                 195 cca gct tat gat gaa aac aag cgc cag ttt caa gaa gat atc aag  630 Pro Ala Tyr Asp Glu Asn Lys Arg Gln Phe Gln Glu Asp Ile Lys                 200                 205                 210 gtg atg aac gac cta gta gat aaa att att gca gat cgc aaa gca  675 Val Met Asn Asp Leu Val Asp Lys Ile Ile Ala Asp Arg Lys Ala                 215                 220                 225 agc ggt gaa caa agc gat gat tta tta acg cat atg cta aac gga  720 Ser Gly Glu Gln Ser Asp Asp Leu leu Thr His Met Leu Asn Gly                 230                 235                 240 aaa gat cca gaa acg ggt gag ccg ctt gat gac gag aac att cgc  765 Lys Asp Pro Glu Thr Gly Glu Pro Leu Asp Asp Glu Asn Ile Arg                 245                 250                 255 tat caa att att aca ttc tta att gcg gga cac gaa aca aca agt  810 Tyr Gln Ile Ile Thr Phe Leu Ile Ala Gly His Glu Thr Thr Ser                 260                 265                 270 ggt ctt tta tca ttt gcg ctg tat ttc tta gtg aaa aat cca cat  855 Gly Leu Leu Ser Phe Ala leu Tyr Phe Leu Val Lys Asn Pro His                 275                 280                 285 gta tta caa aaa gca gca gaa gaa gca gca cga gtt cta gta gat  900 Val Leu Gln Lys Ala Ala Glu Glu Ala Ala Arg Val Leu Val Asp                 290                 295                 300 cct gct cca agc tac aaa caa gtc aaa cag ctt aaa tat gtc ggc  945 Pro Val Pro Ser Tyr Lys Gln Val Lys Gln Leu Lys Tyr Val Gly                 305                 310                 315 atg gtc tta aac gaa gcg ctg cgc tta tgg cca act gct cct gcg  990 Met Val Leu Asn Glu Ala Leu Arg Leu Trp Pro Thr Ala Pro Ala                 320                 325                 330 ttt tcc cta tat gca aaa gaa gat acg gtg ctt gga gga gaa tat 1035 Phe Ser Leu Tyr Ala Lys Glu Asp Thr Val Leu Gly Gly Glu Tyr                 335                 340                 345 cct tta gaa aaa ggc gac gaa cta atg gtt ctg att cct cag ctt 1080 Pro Leu Glu Lys Gly Asp Glu Leu Met Val Leu Ile Pro Gln Leu                 350                 355                 360 cac cgt gat aaa aca att tgg gga gac gat gtg gaa gag ttc cgt 1125 His Arg Asp Lys Thr Ile Trp Gly Asp Asp Val Glu Glu Phe Arg                 365                 370                 375 cca gag cgt ttt gaa aat cca agt gcg att ccg cag cat gcg ttt 1170 Pro Glu Arg Phe Glu Asn Pro Ser Ala Ile Pro Gln His Ala Phe                 380                 385                 390 aaa ccg ttt gga aac ggt cag cgt gcg tgt atc ggt cag cag ttc 1215 Lys Pro Phe Gly Asn Gly Gln Arg Ala Cys Ile Gly Gln Gln Phe                 395                 400                 405 gct ctt cat gaa gca acg ctg gta ctt ggt atg atg cta aaa cac 1260 Ala Leu His Glu Ala Thr Leu Val Leu Gly Met Met Leu Lys His                 410                 415                 420 ttt gac ttt gaa gat cat aca aac tac gag ctg gat att aaa gaa 1305 Phe Asp Phe Glu Asp His Thr Asn Tyr Glu Leu Asp Ile Lys Glu                 425                 430                 435 act tta acg tta aaa cct gaa ggc ttt gtg gta aaa gca aaa tcg 1350 Thr Leu Thr Leu Lys Pro Glu Gly Phe Val Val Lys Ala Lys Ser                 440                 445                 450 aaa aaa att ccg ctt ggc ggt att cct tca cct agc act gaa cag 1395 Lys Lys Ile Pro Leu Gly Gly Ile Pro Ser Pro Ser Thr Glu Gln                 455                 460                 465 tct gcc aaa aaa gca cgc aaa aag gca gaa aac gct cat aat acg 1440 Ser Ala Lys Lys Val Arg Lys Lys Ala Glu Asn Ala His Asn Thr                 470                 475                 480 ccg ctg ctt gtg cta tac ggt tca aat atg gga aca gct gaa gga 1485 Pro Leu Leu Val Leu Tyr Gly Ser Asn Met Gly Thr Ala Glu Gly                 485                 490                 495 acg gcg cgt gat tta gca gat att gca atg agc aaa gga ttt gca 1530 Thr Ala Arg Asp Leu Ala Asp Ile Ala Met Ser Lys Gly Phe Ala                 500                 505                 510 ccg cag gtc gca acg ctt gat tca cac gcc gga aat ctt ccg cgc 1575 Pro Gln Val Ala Thr Leu Asp Ser His Ala Gly Asn Leu Pro Arg                 515                 520                 525 gaa gga gct gta tta att gta acg gcg tct tat aac ggt cat ccg 1620 Glu Gly Ala Val Leu Ile Val Thr Ala Ser Tyr Asn Gly His Pro                 530                 535                 540 cct gat aac gca aag caa ttt gtc gac tgg tta gac caa gcg tct 1665 Pro Asp Asn Ala Lys Gln Phe Val Asp Trp Leu Asp Gln Ala Ser                 545                 550                 555 gct gat gaa gta aaa ggc gtt cgc tac tcc gta ttt gga tgc ggc 1710 Ala Asp Glu Val Lys Gly Val Arg Tyr Ser Val Phe Gly Cys Gly                 560                 565                 570 gat aaa aac tgg gct act acg tat caa aaa gtg cct gct ttt atc 1755 Asp Lys Asn Trp Ala Thr Thr Tyr Gln Lys Val Pro Ala Phe Ile                 575                 580                 585 gat gaa acg ctt gcc gct aaa ggg gca gaa aac atc gct gac cgc 1800 Asp Glu Thr Leu Ala Ala Lys Gly Ala Glu Asn Ile Ala Asp Arg                 590                 595                 600 ggt gaa gca gat gca agc gac gac ttt gaa ggc aca tat gaa gaa 1845 Gly Glu Ala Asp Ala Ser Asp Asp Phe Glu Gly Thr Tyr Glu Glu                 605                 610                 615 tgg cgt gaa cat atg tgg agt gac gta gca gcc tac ttt aac ctc 1890 Trp Arg Glu His Met Trp Ser Asp Val Ala Ala Tyr Phe Asn Leu                 620                 625                 630 gac att gaa aac agt gaa gat aat aaa tct act ctt tca ctt caa 1935 Asp Ile Glu Asn Ser Glu Asp Asn Lys Ser Thr Leu Ser Leu Gln                 635                 640                 645 ttt gtc gac agc gcc gcg gat atg ccg ctt gcg aaa atg cac ggt 1980 Phe Val Asp Ser Ala Ala Asp Met Pro Leu Ala Lys Met His Gly                 650                 655                 660 gcg ttt tca acg aac gtc gta gca agc aaa gaa ctt caa cag cca 2025 Ala Phe Ser Thr Asn Val Val Ala Ser Lys Glu Leu Gln Gln Pro                 665                 670                 675 ggc agt gca cga agc acg cga cat ctt gaa att gaa ctt cca aaa 2070 Gly Ser Ala Arg Ser Thr Arg His Leu Glu Ile Glu Leu Pro Lys                 680                 685                 690 gaa gct tct tat caa gaa gga gat cat tta ggt gtt att cct cgc 2115 Glu Ala Ser Tyr Gln Glu Gly Asp His Leu Gly Val Ile Pro Arg                 695                 700                 705 aac tat gaa gga ata gta aac cgt gta aca gca agg ttc ggc cta 2160 Asn Tyr Glu Gly Ile Val Asn Arg Val Thr Ala Arg Phe Gly Leu                 710                 715                 720 gat gca tca cag caa atc cgt ctg gaa gca gaa gaa gaa aaa tta 2205 Asp Ala Ser Gln Gln Ile Arg Leu Glu Ala Glu Glu Glu Lys Leu                 725                 730                 735 gct cat ttg cca ctc gct aaa aca gta tcc gta gaa gag ctt ctg 2250 Ala His Leu Pro Leu Ala Lys Thr Val Ser Val Glu Glu Leu Leu                 740                 745                 750 caa tac gtg gag ctt caa gat cct gtt acg cgc acg cag ctt cgc 2295 Gln Tyr Val Glu Leu Gln Asp Pro Val Thr Arg Thr Gln Leu Arg                 755                 760                 765 gca atg gct gct aaa acg gtc tgc ccg ccg cat aaa gta gag ctt 2340 Ala Met Ala Ala Lys Thr Val Cys Pro Pro His Lys Val Glu Leu                 770                 775                 780 gaa gcc ttg ctt gaa aag caa gcc tac aaa gaa caa gtg ctg gca 2385 Glu Ala Leu Leu Glu Lys Gln Ala Tyr Lys Glu Gln Val Leu Ala                 785                 790                 795 aaa cgt tta aca atg ctt gaa ctg ctt gaa aaa tac ccg gcg tgt 2430 Lys Arg Leu Thr Met Leu Glu Leu Leu Glu Lys Tyr Pro Ala Cys                 800                 805                 810 gaa atg aaa ttc agc gaa ttt atc gcc ctt ctg cca agc ata cgc 2475 Glu Met Lys Phe Ser Glu Phe Ile Ala Leu Leu Pro Ser Ile Arg                 815                 820                 825 ccg cgc tat tac tcg att tct tca tca cct cgt gtc gat gaa aaa 2520 Pro Arg Tyr Tyr Ser Ile Ser Ser Ser Pro Arg Val Asp Glu Lys                 830                 835                 840 caa gca agc atc acg gtc agc gtt gtc tca gga gaa gcg tgg agc 2565 Gln Ala Ser Ile Thr Val Ser Val Val Ser Gly Glu Ala Trp Ser                 845                 850                 855 gga tat gga gaa tat aaa gga att gcg tcg aac tat ctt gcc gag 2610 Gly Tyr Gly Glu Tyr Lys Gly Ile Ala Ser Asn Tyr Leu Ala Glu                 860                 865                 870 ctg caa gaa gga gat acg att acg tgc ttt att tcc aca ccg cag 2655 Leu Gln Glu Gly Asp Thr Ile Thr Cys Phe Ile Ser Thr Pro Gln                 875                 880                 885 tca gaa ttt acg ctg cca aaa gac cct gaa acg ccg ctt atc atg 2700 Ser Glu Phe Thr Leu Pro Lys Asp Pro Glu Thr Pro Leu Ile Met                 890                 895                 900 gtc gga ccg gga aca ggc gtc gcg ccg ttt aga ggc ttt gtg cag 2745 Val Gly Pro Gly Thr Gly Val Ala Pro Phe Arg Gly Phe Val Gln                 905                 910                 915 gcg cgc aaa cag cta aaa gaa caa gga cag tca ctt gga gaa gca 2790 Ala Arg Lys Gln Leu Lys Glu Gln Gly Gln Ser Leu Gly Glu Ala                 920                 925                 930 cat tta tac ttc ggc tgc cgt tca cct cat gaa gac tat ctg tat 2835 His Leu Tyr Phe Gly Cys Arg Ser Pro His Glu Asp Tyr Leu Tyr                 935                 940                 945 caa gaa gag ctt gaa aac gcc caa agc gaa ggc atc att acg ctt 2880 Gln Glu Glu Leu Glu Asn Ala Gln Ser Glu Gly Ile Ile Thr Leu                 950                 955                 960 cat acc gct ttt tct cgc atg cca aat cag ccg aaa aca tac gtt 2925 His Thr Ala Phe Ser Arg Met Pro Asn Gln Pro Lys Thr Tyr Val                 965                 970                 975 cag cac gta atg gaa caa gac ggc aag aaa ttg att gaa ctt ctt 2970 Gln His Val Met Glu Gln Asp Gly Lys Lys Leu Ile Glu Leu Leu                 980                 985                 990 gat caa gga gcg cac ttc tat att tgc gga gac gga agc caa atg 3015 Asp Gln Gly Ala His Phe Tyr Ile Cys Gly Asp Gly Ser Gln Met                 995                 1000                1005 gca cct gcc gtt gaa gca acg ctt atg aaa agc tat gct gac gtt 3060 Ala Pro Ala Val Glu Ala Thr Leu Met Lys Ser Tyr Ala Asp Val                 1010                1015                1020 cac caa gtg agt gaa gca gac gct cgc tta tgg ctg cag cag cta 3105 His Gln Val Ser Glu Ala Asp Ala Arg Leu Trp Leu Gln Gln Leu                 1025                1030                1035 gaa gaa aaa ggc cga tac gca aaa gac gtg tgg gct ggg 3144 Glu Glu Lys Gly Arg Tyr Ala Lys Asp Val Trp Ala Gly                                1040                1045 1048 

1.-20. (canceled)
 21. A mutant CYP102A1 enzyme with enhanced monooxygenase activity and/or altered product selectivity comprising a substitution at one or more of amino acid residue positions 330, 191, 401, 403, 307, 377, 425, 276, 117, 131, or
 215. 22. The enzyme of claim 21 which shares at least 40% homology with amino acid residues 1-480 of CYP102A1, or is a mutant fragment thereof.
 23. The enzyme of claim 21, which comprises 1, 2, 3, 4, 5 or more stretches of at least 15 or at least 20 contiguous amino acids which represent unmutated fragments of CYP102A1.
 24. The enzyme of claim 21, comprising: i) a conservative mutation at one or more of positions 117, 131, 215, 330, 401; and/or ii) a polar amino acid at one or more of positions 191 and 276; and/or iii) a non-polar amino acid at one or more of positions 377 and 403; and/or iv) an uncharged residue at position 425, and/or v) there are no mutations at positions which flank one or more of positions 117, 131, 191, 215, 276, 307, 330, 377, 401, 403 or
 425. 25. The enzyme of claim 21, which additionally comprises substitutions at one or more of the following positions: 47, 51, 74, 82, 87, 171, 188, 239, 259, 263, 264, 267, 319, 328, or
 353. 26. The enzyme of claim 25, comprising mutations selected from the group consisting of: R47L, Y51F, A74G, A82L, F87A, F87G, F87L, H171L, L188Q, N239H, I259V, I263A, A264G, E267V, N319Y, A328V, L353I., and combinations thereof.
 27. The mutant CYP102A1 enzyme of claim 21, wherein said mutant comprises one or more of the following mutations or groups of mutations: i) A330P; ii) A191T/N239H/I259V/A276T/L353I; iii) F87A/H171L/Q307H/N319Y; iv) F87A/A330P/E377A/D425N; v) F87A/A117V/E131D/L215I; vi) I401P; vii) R47L/Y51F/I401P; viii) F87A/I401P; ix) R47L/Y51F/F87A/I401P; x) R47L/Y51F/A330P/I401P; xi) Q403P; xii) R47L/Y51F/Q403P; or xiii) R47L/Y51F/F87A/Q403P.
 28. A process for oxidizing a substrate which is an organic compound, comprising oxidizing said organic compound substrate with a mutant CYP102A1 enzyme with enhanced monooxygenase activity and/or altered product selectivity and further comprising a substitution at one or more of amino acid residue positions 330, 191, 401, 403, 307, 377, 425, 276, 117, 131, or
 215. 29. The process according to claim 28 wherein said substrate is a short-chain alkane, or a substituted derivative thereof, or is an aromatic compound, or an alkylbenzene, or a substituted derivative thereof.
 30. The process according to claim 28 wherein said substrate is a halo aromatic compound or an acyclic or cyclic terpene or a terpenoid or a sesquiterpene, or a cycloalkene or a saturated fatty acid; or a substituted derivative of any thereof.
 31. The process according to claim 29, wherein said short chain alkane is pentane, 3-methylpentane, 2-methylbutane, butane, propane, ethane and methane; or wherein said alkylbenzene is propylbenzene, ethylbenzene, toluene, butylbenzene, t-butylbenzene, o-xylene, m-xylene, cumene, p-cymene, and ethylanisole; or wherein the aromatic compound is naphthalene or fluorene; or wherein said monoterpene is limonene or pinene; or wherein said sesquiterpene is valencene; or wherein said terpenoid is an ionone such as β-ionone or a damascone; or wherein said saturated fatty acid is lauric acid or decanoic acid.
 32. A composition of matter comprising: (I) an antibody which selectively binds mutant CYP102A1 enzyme with enhanced monooxygenase activity and/or altered product selectivity, comprising a substitution at one or more of amino acid residue positions 330, 191, 401, 403, 307, 377, 425, 276, 117, 131, or 215, and which does not bind to CYP102A1; (II) a polynucleotide which comprises a sequence which encodes said enzyme, optionally in the form of a vector; (III) a cell which expresses said enzyme; or (IV) a transgenic animal or plant having said cell.
 33. The composition of claim 32, wherein the cell is a prokaryotic or eukaryotic cell.
 34. The composition of claim 33, wherein the cell is a strain of Escherichia coli, Pseudomonas sp., yeast, Pichia sp., Rhodococcus sp., Bacillus sp.
 35. A process according to claim 28, wherein the organic compound substrate is oxidized in a cell which expresses said enzyme.
 36. A method of treating a locus contaminated with a substrate which is an organic compound comprising contacting the locus with a mutant CYP102A1 enzyme with enhanced monooxygenase activity and/or altered product selectivity and comprises a substitution at one or more of amino acid residue positions 330, 191, 401, 403, 307, 377, 425, 276, 117, 131, or 215 or a mixture of one or more said enzymes, or a cell which expresses said enzyme or mixture or one or more enzymes, or a transgenic animal or plant having said cell.
 37. The process according to claim 28 wherein a different number of products are formed in comparison to if the process were carried out using CYP102A1. 